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Copy No.
NRO REVIEW COMPLETED
VOLUME ONE
PROJECT 9015
FINAL REPORT
1960 -1964
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An Image Processor has been designed and built as a portion of a
coherent high resolution radar system. This unit is an optical device
designed for use in a laboratory on the ground. The Processor accepts
the (unintelligible) data from the airborne equipment and converts it to
a radar "map. " A separate chemical processor is used. to develop the
data and map films.
This report, along with a Final Report on the Processor, covers
all aspects of the program from its inception in 1960 to its conclusion
at the end of 1964. The work included initial studies, the design and
construction of the Processor, the test and modification program, the
operation of the unit in support of the coherent radar system, and, many
ancilliary studies.
The report is published in two volumes, the first is the description
of the project, the second contains several detailed engineering analysis
and other appendixes.
Certain field support activities and studies will run into 1965.
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Page
1. 0 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
1. 1 Purpose of the Processor . . . . . . . . . . . . . . . . . . 4
1.2 Historical Summary of the Project . . . . . . . . . . . . . . 5
2. 0 DESIGN AND CONSTRUCTION OF THE PROCESSOR . . . . . . . 16
3. 0 PERFORMANCE OF THE PROCESSOR . . . . . . . . . . . . . 23
3. 1 Resolution Criteria . . . . . . . . . . . . . . . . . . . . . . 24
3. 2 Azimuth Resolution . . . . . . . . . . . . . . . . . . . . . . 25
3. 3 Range Resolution . . . . . . . . . . . . . . . . . . . . . . . 27
3. 4 Signal to Noise Ratio . . . . . . . . . . . . . . . . . . . . . 29
3. 5 Spurious Images . . . . . . . . . . . . . . . . . . . . . . . . 29
3. 6 Speed of Map Production . . . . . . . . . . . . . . . . . . . 30
3. 7 Map Fidelity . . . . . . . . . . . . . . . . . . . . . . . . . 30
3. 8 Operational Difficulty . . . . . . . . . . . . . . . . . . . . . 30
4. 0 ACCESSORY EQUIPMENT BUILT . . . . . . . . . . . . . . . . . 33
4. 1 First Optical Bench . . . . . . . . . . . . . . . . . . . . . . 33
4. 2 Improved Optical Bench . . . . . . . . . . . . . . . . . . . 33
4. 3 Detail Correlator . . . . . . . . . . . . . . . . . . . . . . . 34
5. 0 DATA SIMULATION . . . . . . . . . . . . . . . . . . . . . . . . . 46
5. 1 Requirements . . . . . . . . . . . . . . . . . . . . . . . . . 46
5.2 Pattern Types and Techniques . . . . . . . . . . . . . . . . 47
5. 3 Ruled Pattern Manufacture . . . . . . . . . . . . . . . . . . 49
5. 4 Continuous Tone Data Simulation . . . . . . . . . . . . . . . 52
6.0 TEST PROGRAM . . . . . . . . . . . . . . . . . . . . . , . . . . 62
6. 1 Resolution in Range . . . . . . . . . . . . . . . . . . . . . . 62
6. 2 Image Size in Azimuth . . . . . . . . . . . . . . . . . . . 67
6. 3 Azimuth Signal Separation . . . . . . . . . . . . . ., . . . . 70
6. 4 Focal Length Compensation . . . . . . . . . . . . . . . . . 72
6. 5 Pattern Tilt . . . . . . . . . . . . . . . . . . . . . . . . . . 73
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TABLE OF CONTENTS (cont'd)
Page
6. 6 Effects of Pattern Focal Length Variations . . . . .. . . . . 75
6. 7 Signal Integration . . . . . . . . . . . . . . . . . . .. . . . . 75
6. 8 Moving Film Tests . . . . . . . . . . . . . . . . . .. . . . . 75
7. 0 STUDIES . . . . . . . . . . . . . . . . . . . . . . . . . .. . . . . 78
7. 1 Early Experimental Work . . . . . . . . . . . . . .. . . . . 78
7.2 Non-Optical Tests . . . . . . . . . . . . . . . . . . . . . . 80
7.2.1 Mirror Mount . . . . . . . . . . . . . . . .. . . . . 80
7.2.2 Liquid Platen . . . . . . . . . . . . . . . . . . . . 81
7.2.3 Film Drive . . . . . . . . . . . . . . . . .. . . . . 81
7. 3 Bandwidth and Aperture Weighting . . . . . . . . . .. . . . . 81
7. 4 Moving Targets . . . . . . . . . . . . . . . . . . . .. . . . . 82
7. 5 Image Analysis . . . . . . . . . . . . . . . . . . . .. . . . . 85
7. 6 Color Bandwidth Correction . . . . . . . . . . . . . . . . . 107
7. 7 Field Curvature . . . . . . . . . . . . . . . . . . .. . . . . 108
7. 7. 1 History of the Problem . . . . . . . . . . .. . . . . 109
7. 7. 2 Measurement and Effect of Field Curvature . . . . 110
7.7.3 Sources of Field Curvature . . . . . . . . .. . . . . 115
7.7.4 Field Curvature Corrective Techniques . .. . . . . 116
7.7.4.1 Field Flattener . . . . . . . . .. . . . . 118
7.7.4.2 Cylinder Lens Pair . . . . . . .. . . . . 118
7.7. 4. 3 Nonlinear Wavelength Filter . . . . . . 119
7.7.4.4 Bent Imaging Cylinder . . . . . . . . . . 119
7.7. 4. 5 Collimating Lenses . . . . . . . . . . . 120
7. 8 Noise and Stray Light . . . . . . . . . . . . . . . . . . . . 120
7. 8. 1 Sources of Stray Light . . . . . . . . . . . . . . . 121
7. 8. 2 Effects of Stray Light . . . . . . . . . . . . . . . . 122
7.9 Film Response . . . . . . . . . . . . . . . . . . . . . . . . 123
7.10 Cone Lenses . . . . . . . . . . . . . . . . . . . . . . . . . 125
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TABLE OF CONTENTS (cont'd)
Page
8. 0 PROGRAM SUPPORT . . . . . . . . . . . . . . . . . . . .. . . . 127
8. 1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 127
8.2 Procedure . . . . . . . . . . . . . . . . . . . . . . . . . 129
8.3 Flight Test Results . . . . . . . . . . . . . . . . . .. . . . 131
8.4 Field Support . . . . . . . . . . . . . . . . . . . . . . . . 132
8.5 Note Added in 1965 . . . . . . . . . . . . . . . . . .. . . . 134
8.6 System Support . . . . . . . . . . . . . . . . . . . .. . . . 134
10.0 DOCUMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . 140
10.1 Final Report, Model 9015 Processor . . . . . . . . . . . 140
10.2 Final Report, Test and Simulation Program . . . . . . . 140
10.3 Operational Manual . . . . . . . . . . . . . . . . . . . . . 140
10.4 Monthly Reports . . . . . . . . . . . . . . . . . . . . . . 141
10.5 Drawings . . . . . . . . . . . . . . . . . . . . . . . . . . 141
10.6 Spares . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
10.7 Acceptance Tests . . . . . . . . . . . . . . . . . . . . . . 141
11.0 SUMMARY, CONCLUSIONS AND RECOMMENDATIONS . . . . 143
11.1 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . 143
11.2 Recommendations . . . . . . . . . . . . . . . . . . . . . 144
11.2.1 9015 Processor . . . . . . . . . . . . . . . . . . 144
11.2.2 Improved Processor . . . . . . . . . . . . . . . 144
11.2.3 Further Studies . . . . . . . . . . . . . . . . . . 145
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LIST OF APPENDIXES*
I. DOCUMENTS
II. INVESTIGATION INTO LIQUIDS SUITABLE FOR IMMERSION PRINTING
III. EFFECTS OF FINITE BANDWIDTH IN THE LIGHT SOURCE
IV. INSTALLATION REQUIREMENTS
V. SPARE PARTS
VI. DETERMINATION OF THE VELOCITIES OF MOVING TARGETS
VII. APERTURE WEIGHTING
VIII. INTERFERENCE PATTERN GENERATOR
IX. STRAY LIGHT IN THE PROCESSOR
X. CYLINDER LENS EFFECTS
XI. FLIGHT TEST REPORT FORMS
XII. EFFECT OF FILM EXPOSURE ON RECORDER/CORRELATOR
PERFORMANCE
XIII. COHERENT SLR RECORDER-CORRELATOR SYSTEM
XIV. TWO DIMENSIONAL HOLOGRAMS
XV. SPECTRUM AND OUTPUT FOR OPTICALLY CORRELATEI) CHIRP
SYSTEM
Itek Document Number SHC65-9015-314/Z, Volume Two.
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Figure Page
1 9015 Processor . . . . . . . . . . . . . . . . . . . . . . . . . 3
2 Block Diagram of Coherent Radar . . . . . . . . . . . . . . . 6
3 Sample Data (Input) Film . . . . . . . . . . . . . . . . . . . . 7
4 Output Print . . . . . . . . . . . . . . . . . . . . . . . . . . 8
5 Processor-Optical Parts . . . . . . . . . . . . . . . . . . . . 18
Processor-Interior View . . . . . . . . . . . . . . . . . . . . 19
Optical Schematic . . . . . . . . . . . . . . . . . . . . . . . 20
Overall View of Bench Correlator . . . . . . . . . . . . . . . 36
Laser Source on Bench Correlator . . . . . . . . . . . . . . 37
Liquid Platen on Bench Correlator . . . . . . . . . . . . . . 38
Details of Rider Assemblies on Bench Correl.ator . . . . . . 39
35 mm Camera . . . . . . . . . . . . . . . . . . . . . . . . . 41
Output Image Viewing Accessories on Bench Correlato:r . . . 42
Ruling the Master Zone Plate . . . . . . . . . . . . . . . . . 50
Zone Plate Sub-masters . . . . . . . . . . . . . . . . . . . . 51
Full Scale Prints of Zone Plates . . . . . . . . . . . . . . . . 56
Overlapped Zone Plates . . . . . . . . . . . . . . . . . . . . 57
Test Film . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
Range Resolution Test Image . . . . . . . . . . . . . . . . . 65
Dot Images . . . . . . . . . . . . . . . . . . . . . . . . . . . 66
Azimuth Line Image . . . . . . . . . . . . . . . . . . . . . . 68
Microphotometer Trace of Fig. 22 . . . . . . . . . . . . . . 69
Azimuth Line Separation . . . . . . . . . . . . . . . . . . . . 71
Effects of Wavelength Variation . . . . . . . . . . . . . . . . 74
Results of First Correlator Experiments . . . . . . . . . . . 79
Moving Target Detection . . . . . . . . . . . . . . . . . . . . 84
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LIST OF FIGURES (cont'd)
Figure Page
Image Variations with Focus Shift . . . . . . . . . . . . . . 105
Corner Reflector Test Targets . . . . . . . . . . . . . . . . 106
Azimuth Image Field Curvature (Near) . . . . . . . . . . . . 112
Azimuth Image Field Curvature (Far) . . . . . . . . . . . . 113
Azimuth Magnification Across Field . . . . . . . . . . . . . 114
Field Curvature Correction Techniques . . . . . . . . . . . 117
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Table
Page
1 Construction Schedule of Processor . . . . . . . . . . . . . . . .
10
2 Factors Affecting Azimuth Resolution . . . . . . . . . . . . . . .
26
3 Summary of Azimuth Resolution of Correlator . . . . . . . . .
28
4 Single Targets Suitable for Static Testing . . . . . . . . . . . . .
53
5 Targets Exposed on Long Lengths of 9Z Inch Wide Film . . . . .
54
6 Parameters of Test Pattern T115 . . . . . . . . . . . . . . . . .
55
7 Flight Test Support . . . . . . . . . . . . . . . . . . . . . . . .
128
8 F101 Flight Film Code Numbers . . . . . . . . . . . . . . . . . .
130
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INTRODUCTION
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1. 0 INTRODUCTION
The Itek Corporation has designed and built the Model 9015 "Image
Processor" shown in Fig. 1. This Processor is a portion of the coherent
high resolution radar system AN/APQ-93 . The Processor was designed
in 1960-61, built in 1961, improved in 1962 and 1963, and has been used
to support various test programs since the beginning of 1962.
The radar system was intended to advance the state-of-the-art by an
order of magnitude, a challenging goal for a three year program. The perfor-
mance of the system, although not quite as good as the 'Initial goals, is as good
or better than any current system known to us. The "azimuth" performance
normally achieved on flight test films is 10 foot ground resolution, and labora-
tory correlation has achieved 5 foot resolution.
The program was initiated with the intent that the equipment could be
quickly built and would be operating reasonably near the design goals after
only a short shake-down period. This intent was implemented by a design
philosophy which emphasized simple techniques that could be predicted to
work with the greatest degree of confidence. Weight, cost, flexibility, and
ease of operation were not ignored, but were secondary considerations.
The airborne radar electronics and antenna were built by the Westinghouse
Corporation. The airborne recorder was built on a separate project by Itek
on subcontract to Westin house.
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__ P F G I A L I-1 A ICI u ,_. IAN %0
Figure 1
This is a rear view of the cabinet which houses the optics and film drives.
The cabinet is approximately 6 feet high. The carbon arc is shown on the
left, the exterior control panel is at the right. An interior front view is
shown in Fig. 5, other views are included in reference 1.
CZ MFC I Al 1-IAKIMI I ICI( 3
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During the course of the system program various problems were encoun-
tered in series, and the treatment of these lead into a three year program.
Some of the problems have been corrected by more sophisticated designs,
some by the application of new knowledge, and some are not yet satisfactorily
corrrected. Many of the remaining problems can be corrected by techniques
which have been developed, but they are expensive and have not been imple-
mented as of now. The Processor is adequate to support the system test
program at the present time.
This report describes all phases of the 41 year program except the con-
struction of the Processor, which is covered in the Model 9015 Processor
Final Report published in May 1964. The appendixes contain a substantial
amount of detailed engineering analysis on subjects directly related to the
project. Some of these appendixes have been previously published and some
are appearing in published form for the first time. Section 7. 0 of this report
presents material which has not been previously reported. Of particular
interest is Section 7. 5, which describes some investigations relating to the
potential usefulness of the output radar map.
This report covers the period from the inception of the program in 1960 up
to the end of 1964. The final editing was done in June 1965, and a. few remarks
and additions were made at that time to bring the text in agreement with the
latest knowledge. However, this report does not describe the work done in 1965.
.1. 1 Purpose of the Processor'
The Processor is an integral part of the coherent radar system shown in
The word Processor will be used in this report to indicate the device shown
in Fig. 1. The word correlator will be used to include all optical correlators
including the bench correlator and the Processor. The name Processor is not
to be confused with the common terminology as the name for a device that
chemically processes a film.
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Fig 2. The airborne system is designed to detect and record the phase
and amplitude of the return signals. This technique collects the data which is
necessary for a high resolution in the azimuth direction, but the data is unin-
telligible as recorded, see Fig. 3. The data is stored on photographic film
which is then returned to the ground station for chemical developing. The
film is inserted into the Processor which "processes" the data into an intel-
ligible high resolution radar map as shown in Fig. 4. This map film is the
end product of the radar system. It is also possible to insert the data film
(or a duplicate of the data film) into a "detail correlator" which presents a
correlated map of any small area directly on a viewing screen.
The Processor is designed to accept and properly "decode" or process
the data generated by the associated radar unit. It does not require any ad-
ditional inputs, although the system could be designed such that certain flight
parameters would be recorded and used to control adjustments in the Processor.
This Processor will not handle the data from any other known coherent radar
system, although it could be modified for other systems which use film as
the basic storage medium.
1. 2 Historical Summary of the Project
The project began early in 1960 when
asked Itek and Westinghouse to consider building a coherent radar system.
Representatives of
considered the technical problems
in proposal studies and joint meetings during the Spring. They decided that
the system could be built. The technical approach and plan of work was pre-
sented to the customer which called for a flight test
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r
D
Z
v
Stable
Local
Oscillator
Pulse
z Antenna
G)
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Airborne fIi Ground Based
Auxiliary
Control
Electronics
Chemical
Processing
Figure 2
Target
Block Diagram of Coherent Radar
Image
Processor
Detail
Correlator
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Map Film r
Visual
Sri mination
High
Resolution
Map Areas
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Figure 3
Sample Data (Input) Film
This is a positive duplicate of a section of the film from flight S87.
Note: In order to display a good example of the Flight
Film data and also give a good impression of the
format, the data blocks from run S93 have! been
dubbed onto the S87 film (the data flash was
turned off in the S80 series, the S90 series is a
shakedown of a new radar set).
The clock and data card are repeated at approximately 12 inch intervals
(about 10 second between flashes in the recorder). The nearest range is
at the top, the furthest range is at the bottom. The gap in the center is
due to an optical offset in the recorder, the actual ground data lost can
be very small (see Appendix II of the Processor Final Report for details).
The short horizontal lines spaced approximately an inch apart in range
are reference range marks made every 9. $1 sec from the transmitted
pulse.
The format is given in reference 1, Fig. 6.
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Figure 4
Output Print
This is a contact print made from the correlation of the data of Fig. 3.
This is made from the near range half of Fig. 3, it is enlarged 2X in the
range direction. In azimuth it is reduced 4. 3X, so it is made from over
2 feet of data film.
The area shown is Martinsberg, West Virginia. The scale is about
12 inches = 1 mile. The airport is south of the town, and a large V.A.
hospital is near the road east of the airport. The dark range reference
marks can be seen north of the hospital. The streak along the center is
due to a joint in the interference filter (see Page 39 and 40 in the Pro-
cessor Final Report).
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demonstration late in 1961. That proposal included the ground based image
processor which is the subject of this report.
The Processor program was initiated upon receipt of authorization on
4 August 1960 and assigned Itek Project No. 9015. The staffing of the pro-
ject began immediately. The first engineer started the experimental pro-
gram to obtain the information required for the detailed design. By Novem-
ber most technical aspects were understood well enough to proceed with the
basic design. The schedule of events in the construction of the Processor
is shown in Table 1.
A set of guiding specifications were written for each subassembly in
December. In February 1961 over 25 engineers, designers, and draftsmen
were at work. At that time a detailed production schedule indicated comple-
tion by the end of August. During the winter and spring a number of design
features were checked with breadboard models where feasible. Considerable
attention was given to the optical design, optical mountings, and film drive.
The basic design of most subassemblies was complete in May and a design
review was held with the customer's technical representative on 16 May 1961.
The fabrication and assembly proceeded rapidly during the summer of
1961. It was expected that the unit would be finished in August, but a num-
ber of minor assembly problems and parts shortages arose to delay comple-
tion. The project did not go on an overtime crash basis since the vendors
for some essential optical parts were behind schedule..
The basic unit was essentially complete in October. It was aligned and
adjusted during November and a preliminary acceptance test was run.
The optical recording system to transfer the clock and data card to the out-
put film was not complete.
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19
60
1961
Nov
Dec
Jan
Feb
Mar
Apr
May
Jun
Jul
:!Au
Sept
Oct
Nov
Dec
Basic o
tical confi
uration
p
g
Sub assembl
s
ecifications
y
p
O
tical desi
n
p
g
Mechanical desi
n & draftin
g
g
Design review
Optical fabrication
M
h
i
l f
b
i
ti
--
ec
an
ca
a
r
ca
on
Electrical desi
n & wirin
g
g
Assembly
Alignment & test
PrAliminar~r acceptance test
n
Table 1
Construction Schedule of Processor
This is an approximate schedule for the Processor as ori-
ginally built. The end dates indicates about 90% complete.
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The early correlation experiments had shown the need for simulated input
data and extensive testing to determine the characteristics of this new device.
While the fabrication proceeded during the summer a Test and Simulation pro-
gram was proposed and work was started to make simulated targets. This
testing program gradually expanded until it represented the bulk of the effort
by January 1962.
In February 1962 the optical system and film drive were modified to
accept longer focal length targets on the data film. The unit was used to
process the first F101 flight films in March, and a recognizable radar map
was obtained from Flight Sli in May 1962.
The Test and Simulation program proceeded rapidly during the first five
months of the year. At the end of May all testing that could be done with the
old cylinder lenses was complete. It had been hoped that new lenses would
be available by the end of May, but technical difficulties delayed delivery of
a complete set of cylinder lenses until November. During the summer and
fall, sixteen F101 flight test films were processed, a number of improve-
ments were made in the mechanical parts of the Processor, and the first
draft of a handbook and final report were written.
The installation of new cylinder lenses and the ten inch wedge interfer-
ence filter in November 1962 brought new effort to improve the performance
test results and the quality of the F101 flight test maps. This effort gained
some immediate improvements and a report on the Test and Simulation
program was written.
It was soon realized that further theoretical and experimental work was
needed to fully integrate the Processor into the overall radar system. The
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Processor had been designed for routine operational use and was poorly adapted
for the continued testing, adjusting, and modifying that had occured in 1962 and
probably would continue throughout the development program. Furthermore,
many of the provisions for routine operation were no longer adequate due to
the difference between original assumptions and actual operation.
A number of modifications were incorporated into the Processor during
1963 to eliminate most of the problems. They included a viewing station with
a 4 x 5 camera back (February), a TV remote viewing capability (installed
temporarily in March and completed in October),a new zero order stop in
the relay lens (April), a new liquid platen with film guides (July), a new film
drive (August), and a new data optics system (December).
The overall testing program continued to obtain better performance data.
The work was expanded to include system effects. Considerable theoretical
and experimental work was done on both the Processor and Recorder pro-
grams to obtain a better understanding of the system and improve the overall
results. New precision simulated test targets were made to support the more
exacting tests. An experimental Processor was built to support some of the
tests, prove out new techniques and provide an emergency back-up for the
Processor in the field.
The newly developed laser is the ideal light source for correlation and
one was purchased for use on certain tests as well as to gain knowledge re-
quired for a second generation Processor. The basic designs for such a
processor were formulated and have been kept up to date so as to keep the
customer informed of potential technical advances.
The airborne recorder was built by Itek on a separate project.
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The on-axis performance of the optical system was tested and found to be
near the diffraction limit. Efforts to improve the overall map film quality
brought out two unforeseen optical problems, an optical bandwidth effect and
a field curvature. The first effect caused a larger loss in resolution due to
the wavelength band than was originally realized. The second effect was found
to be due to two unusual optical effects in the relay and cylinder lenses. Each
of these problems received considerable attention, but feasible solutions were
found to require more time and money than was justified on the present Pro-
cessor.
Stray light is a serious problem in the correlator. An extensive study was
made of the sources of stray light and some improvements in stray light level
were realized by making suitable modifications to the unit and procedures.
Further improvements would require major changes and hence are recom-
mended for the next correlator built.
Two company sponsored programs also contributed to this project in 1963.
The first was an experimental program to make simulated target data by holo-
gram generation techniques. This work was implemented with the laser and
succeeded in making and reconstructing good holograms. The second program
was the development of a capability to fabricate cone lenses at Itek. A simple
cone lens was fabricated and tested and found to be close to our requirements.
It was concluded that a cone lens could be made when :required.
A final acceptance test on the Processor and associated optical equipment
was performed in December 1963. In the first two months of 1964 some tests
were run which indicated a limiting resolution of less than . 0007 inches
(measured at the output film) for the Processor. The overall system resolved
*Some new minor modifications are being considered.
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targets spaced by 20 feet. Later in the year corner reflector targets spaced
8 feet apart were detected and recorded on the bench, and targets 10 feet apart
were resolved on map films made in the Processor.
The Processor was shipped to in March 1964. Itek STAT
personnel set up and operated it. The unit was used primarily in support of
the continuing F101 tests. A number of accurate measurements of field cur-
vature, magnification, and film drive ratio were made. In November the
Processor and personnel were re-located at the Westinghouse plant in Balti-
more to be closer to the electronic engineers and the F101 test operation.
The effort in Lexington during 1964 was devoted to the writing of a final
report on the Processor, support of other phases of the program, and specific
studies. The Processor Final Report (reference 1) was written early in the
year and published in May. There were no important changes made to the
Processor after shipment, so that report is still correct. The bulk of this
Project Final Report was drafted late in 1964.
The support functions included routine correlation of the F101 flight test
films, engineering back-up of the field personnel, theoretical and experi-
mental support of the overall program and of specific tests run at Baltimore,
and the generation of proposals for further improvements and second genera-
tion equipment.
The studies included the investigations of variable density aperture
weighting filters, the experimental and theoretical analysis of the field
curvature problem and methods to correct it, the detection of moving
targets and close analysis of the image structure obtained on the output
map film.
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DESIGN AND CONSTRUCTION OF THE PROCESSOR
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2. 0 DESIGN AND CONSTRUCTION OF THE PROCESSOR
The production of the Processor was originally the only task on Project
9015. Its design and construction constituted the entire program for the first
year and continued to be the major portion of the effort until the end of 1963.
The work on the Processor was described in full in a report written in
May 1964 entitled "Final Report Model 9015 Processor" (reference 1). That
report can be considered as part of this Project Final Report, and the reader
is referred to it for a discussion of that phase of the project. The only
changes to be made are as follows:
Page 4, Fig. 3 Refer to Fig. 6 of this report for an up
to date photo.
Page 5, Fig. 4 Refer to the current log book for up to
Page 7, Fig. 6 date data. (There are no major changes
Page 9, Fig. 8 as of 6/l/65. )
Page 13, second paragraph The results of these studies are given
in Sections 3. 0 and 5. 0 of this report.
Page 21, second paragraph For more detailed operational require-
ments, see Appendix IV of this report.
Page 29, Fig. 14 Refer to Fig. 6 of this report for an up
to date photo.
Page 30, last sentence See Section 7. 7 of this report.
Page 49, second paragraph At present one wheel is in use. It
covers a 11% range and is adequate
for present needs.
Page 50, end of page Film mistracking had not been a seri-
ous problem in the field. This is due
to the improved design, routine opera-
tion, and relaxed requirements.
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The theory of operation is discussed in the "Processor Final Report", but
a brief section will be reproduced here for ready reference.
Two front views of the unit are shown in Figs. 5 and 6. The former
photograph shows the optical parts and film drives, but is obsolete in some
details, the second photo was taken recently. The optical schematic is shown
in Fig. 7. The carbon arc is focused by the condenser lenses onto the input
slit (5 to 40,tc wide). The collimator forms the plane wavefront to strike the
data film and the field lens refocuses the beam onto the zero order stop.
This opaque baffle stops all the light except that diffracted into the real image
by the zone plate pattern. A pattern in the platen will. have formed a diffrac-
tion image at a distance of 150 inches (or 200 inches). This is reimaged by
the field lens to a point about 2 inches from the zero order stop. The cylin-
der lenses refocus it onto the output platen. In the original design (for the
24" focal length patterns) one cylinder lens was used but two lenses are re-
quired for the 150" patterns to avoid mechanical interference with the mirror.
The wedge interference filter which selects the wavelength for each range
must be located at or near a range focus. This occurs at the input platen and
again at the output platen. The original design used a. filter at the input platen,
but the 150" targets demanded a 3 inch wide filter, which could not be fabri-
cated. The filter was shifted to the output, where the width requirement is
less than 2 inch. Unfortunately, the vendor had to make the 9 inch length by
butting two 5 inch filters, which leaves a streak down the center of the output
film (see Fig. 4). This can be eliminated whenever the vendor obtains suitable
equipment and the cost is justified.
The optical system in the range direction is an enlarger which uses the
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)I-'GL. IA.%L r1HIN L)___ I IN
Figure 5
Processor-Optical Parts
This is an early (1962) photograph of the interior of the Processor. The
optical parts can be clearly seen and are identified by number (numbers
are the same as those on Fig. 7). The film path can be followed by re-
ferring to the threading diagram seen in the next photo (Fig. 6). The
function of the electrical controls can also be seen in Fig. 6.
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Figure 6
A recent (1965) photograph of the interior of the Processor. Many changes
and additions have been made as can be seen by comparison with Fig. 5.
The TV camera is at the lower right, its lens is looking upward toward the
output image area.
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P2
v
2.64 Plr
1
8 P2
P21
I T 3 -
j .15
PSI,
ij
8.72
P
\
6.34 84;
P2
1.
Carbon arc
2.
Condenser system
3.
Heat sink
4.
Slit
5.
Top mirror
6.
Collimator lens
7.
Upper platen
8.
Input film
sa
9.
Lower platen
10.
Field lens
is
11.
Zero order stop
18
12.
Relay lens
13.
Fixed cylinder lens
14.
Bottom mirror
15.
Interchangeable cylinder lens (far)
13.73
16.
Interchangeable cylinder lens (near)
17.
Balancing filter
18
Wedge interference filter
20.89
.
19.
Platen roller
20.
Output film
Figure 7
Optical Schematic
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relay lens to magnify the range by a factor of 2. This magnification was ori-
ginally chosen on the basis of using Plus X as the optimum film for achieving
adequate resolution with the highest operating speed.
The exit slit is not critical, and merely limits the width of field used.
The optical system forms an image about one half inch wide, the slit is
usually set . 100 inch wide. The width of the slit can be shaped to give a
uniform exposure across the field if desired.
The performance of the Processor is discussed in. Section 5.0 of the Pro-
cessor Final Report. That discussion is still basically correct, except that
experience and improved adjustments have given improved azimuth resolution.
The following chapter covers this topic in further detail.
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3. 0 PERFORMANCE OF THE PROCESSOR
The performance of the Processor and bench correlator cannot be simply
specified independent of the overall radar system. During the course of the
project the performance has been discussed and measured in many contexts
ranging from a single optical element to the overall radar system. Previous
attempts to convert the information to one figure has often led to confusion
and tends to reduce the usefulness of some of the tests. Therefore, in this
summary a number of measures of performance will be given so that the
reader can deduce whichever values he is interested in.
This section will only summarize the findings, further details of the
tests and data will be found in Section 6. 0 of this report and in the Processor
Final Report.
The performance of the correlators (and of the entire radar system) can
be considered in the following categories:
azimuth re solution
range resolution
signal to noise ratio
spurious image content
fidelity of the map
speed of map production
operational difficulty
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The azimuth resolution has received the greatest amount of attention,
largely because it is the chief reason for using a complex coherent radar
system and is the most affected by the problems encountered in the equip-
ment. The range resolution is not unique to the coherent system, and the
correlator has adequate resolution to handle the films currently available.
Items 3, 4 and 5 are very complex and few definitive results can be ex-
pected until the equipment is performing satisfactorily. The (considerable)
effort to date has resulted primarily in system improvements rather than
performance data. Items 5 and 7 are not really performance characteris-
tics, but are included in the list primarily because they involve many
trade-off items which also affect the other parameters.
3. 1 Resolution Criteria
The resolution information can be obtained and interpreted in many ways.
The most sophisticated method is to measure the density profile of the image
from a point object (i. e. a perfect hologram in the case of azimuth direction).
In ordinary optical systems this is theoretically equivalent to the sine wave
response function. A simpler and more common method is to measure the
apparent image width or determine the smallest image separation that is just
resolvable. These techniques are subject to the observer's judgement and
also to exposure and film contrast variations, but when properly done are
accurate to 20% or better.
Early in the program it was suspected that there might be a significant
difference between the single line width measurement and resolvable pair
measurement due to the FM capture phenomenon. Experience has shown
that the resolution measurement is little affected by this effect. In this
''`Known as the spread function.
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report data taken as a line width or minimum resolvable distance has been
considered as equivalent.
3. 2 Azimuth Resolution
The azimuth resolution is the most important performance factor, and
also the most difficult to measure and interpret in terms of the overall radar
system performance. Most of the novel aspects of the system bear directly
on the azimuth performance, and so most of the problems have been associated
with it. A list of the factors which influence azimuth resolution is given in
Table 2; it could almost substitute for the table of contents for this report.
The basic optical system gave an image width of 0. 0007 inch when tested
on the bench correlator with an extremely narrow slit, very small bandwidth,
essentially perfect ruled target, and extra optical magnification to reduce the
effect of output film resolution. This test was repeated in the Processor and
an image separation of 0. 0018 inch was clearly resolved with the carbon arc
and interference filter. An image separation of 0. 0009 inch was resolved
visually, and it was estimated that a separation of 0. C)007 inch would have
been obtained if the experiment could have been pursued further.
A microdensitometer trace was made of a line exposed in February 1963.
At that time the resolution was degraded somewhat by a wide (15/4) entrance
slit and a target of questionable accuracy. However, the curve (shown in
Fig. 23 on page 69) does show the expected shape.
The best resolution obtained while the input and output film were running
has been . 0028 inch image separation obtained with test target #T150 and the
0. 4% bandwidth wedge interference filter.
The finest resolution obtained on F101 flight test film is .0007 inch
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Factors Affecting Azimuth Resolution
1. Diffraction limit
(a) radar antenna beam characteristics
(b) optical aperture, including effects of aperture weighting if any
2. Lack of perfection in optical system
(a) on-axis aberrations
(b) off-axis aberrations
(c) effective field curvature
3. Correlator illumination
(a) incorrect wavelength
(b) finite band of wavelengths
(c) width of input slit
4. Image motion
(a) incorrect image tracking rate
(b) vibration
5. Imperfections in input data
(a) non-linear range sweep rate
(b) phase and amplitude imperfections in recorded target history
6. Incorrect adjustments
(a) lack of accurate information about input data
(b) lack of precision calibration of correlator
(c) lack of ability to adjust correlator to give optimum image
7. Adjustment trade-off
(a) speed of processing
(b) ease of operation
(c) signal to noise ratio
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obtained on the bench correlator from two corner reflectors spaced 4 feet
apart.
The best static resolution obtained on the Processor from F101 data is
.0014 inch visually (and on the TV) from 10 foot reflectors on S107. Dynamic
photographic runs did not quite resolve these targets, the resolution is esti-
mated to be about . 0018 inch on one of the runs.
The resolution figures quoted above are for one local area when that area
is in optimum focus. This represents the ultimate resolution that can be
achieved when studying one area. However, the average resolution across
a 9 inch map is much lower because of an azimuth image field curvature.
This causes most of the map to be out of focus and to have a tracking error
as is explained in Section 7. 7. The resolution variation depends upon the
focus compromise chosen; for most practical work the resolution varies
from . 0025 inch a short distance from the center to . 003 or . 0035 inch at
the center and . 010 inch near the edges.
The AWAR (Area Weighted Average Resolution) has not been measured
for F101 maps. This is partly due to the lack of targets of known character-
istic across the entire width of a film, and partly due to the fact that the test
program has concentrated on obtaining good maps in the center. The edges
of the map have not been ignored, but the steps required to achieve good
resolution are too expensive to be warranted for the purposes of the F101
program.
The performance is summarized in Table 3.
3. 3 Range Resolution
The range resolution of the Processor depends on the resolution of the
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Summary of Azimuth Resolution of Correlators
.0007 inch bench correlator, laser source, approximately 1
square mile field of view. This is the limit of
resolution on the best input films.
.0018 inch best results from Processor. Obtainable over 1
mile range interval for full length of film. Usually
requires more than one correlation run.
.0025 inch resolution obtained on good run over 2 mile range
.0035 inch average resolution over center 6 inches of map
.006 inch average resolution across entire (9 inch width)
map film.
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relay lens, effects of the cylinder lens, film tracking, and the film resolu-
tion. In the airborne system the resolution is limited. by the effective
pulse width, receiver bandwidth, chirp compression ratio, CRT and recorder
optics resolution, and sweep stability.
The resolution of the relay lens has been measured visually as 65 1/mm
on axis and 45 1/mm off axis referred to the output. Measurements in the
processor indicate a line width of .0007 inch or less on axis and . 0011 inch
off axis.
The effects of the cylinder lens are negligible when properly aligned as
indicated in Appendix X. Likewise the loss due to poor film tracking can
theoretically be reduced to zero and in practice has usually been negligible.
The film in current use has an effective line width of about .0005 inch.
Typically, the resolution on the F101 data film has been about . 005 or
larger (referred to the output). This relatively large width has de-empha-
sized further study of the correlator range performance.
3. 4 Signal to Noise Ratio
At present there is no meaningful data on signal to noise ratio or noise
insertion by the correlator. Attempts to measure these quantities have lead
to a reduction of stray light but have not given meaningful data. For a quali-
tative assessment of the signal to noise ratio the reader is referred to Fig. 4.
3. 5 Spurious Images
Most sources of spurious images are inherent in the airborne equipment
and the data film sensitometry. However, spurious images can be produced
by multiple reflection in the optics of the correlator. The only serious
source of such images in the Processor has been the interference filter, and
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this has been mounted in a holder to eliminate these images. On the bench
correlator the output film does not move, so all multiple reflection images
focused on the image plane are reproduced as spurious images. These
usually appear as long lines and thus are not normally confused with real
images.
3. 6 Speed of Map Production
The speed of map production in the Processor is normally 3 feet per
hour. This 3 feet of film contains a map 28 miles long for F101 flight
tests.
There has been no attempt to adapt the bench correlator for map produc-
tion. A one second exposure is required for a 5X enlargement of about one
half square mile.
3. 7 Map Fidelity
This can be considered in two parts, dimensional. accuracy and image
fidelity. There has been little interest in the dimensional accuracy on this
program and no data is available, but it can be estimated that dimensions
are probably correct to within 1% in azimuth. In the range direction there
are built in distortions, if rectified the accuracy would probably be better
than 1 %.
The image fidelity or correspondence between target and image is diffi-
cult to define because of the lack of knowledge of how the targets appear.
This subject is discussed in Section 7. 5, and no attempt will be made to
summarize the findings here.
3. 8 Operational Difficulty
An unmeasurable but important quality is the difficulty of operating the
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equipment. In general the interplay of the actual aircraft perturbations and
radar performance on the recorded data is not known to the Processor oper-
ator, Therefore, for optimum focusing several cut and try runs are required.
On the other hand, the Processor is fairly easy to operate to obtain routine
maps which are 80% as good as can be optimally attained. The bench correla-
tor can easily vary tilt, focus, exposure, offset or filtering to optimize any
particular area, but it is very difficult to make a large area map. At present,
the best analysis is obtained by using both correlators?
The specifics of the operational difficulties will not be summarized here,
the reader is referred to Section IV of the Processor Final Report, and the
instruction manual for details.
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ACCESSORY EQUIPMENT BUILT
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4. 0 ACCESSORY EQUIPMENT BUILT
A number of auxiliary optical test devices have been built to simulate
various aspects of correlation or to perform specific tests. These have all
been built on an optical bench foundation to provide for flexibility of use.
4. 1 First Optical Bench
The first test unit was a bench fabricated in 1960 to obtain basic data
about correlation. A mercury arc lamp was mounted on one end of the bench
and its light focused onto a slit. A small aperture collimator of conventional
design was used to collimate the light, and a high quality camera lens (180
mm focal length Componon) was used to form the zero order image and cor-
relation images. Black wire was used to stop the zero order light. Some
simple cylinder lenses were used to obtain range imaging. A 35 mm camera
back with focal plane shutter was used as a film holder. This bench was re-
placed with the better benches below, but the base and many of the parts are
still in use.
>,c
4.2 Improved Optical Bench
The second bench was built in 1962 to support more exacting experiments.
This had provision for better alignment, better optics, and capability to insert
92 inch F101 flight films. A 5 x 7 inch immersion platen was built and used
for correlation experiments. Selected areas of the data films were contact
'`This unit was also known as the Experimental Processor.
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printed and these prints inserted into this platen. The lenses from the Pro-
cessor could be mounted for testing or to support other experiments. The
cylinder lens rider provided precision rotational adjustment around the
optical axis.
The bench was used extensively for frequency spectrum analysis, es-
pecially in connection with the recorder project. The general appearance
of the bench is shown in the Processor Final Report on page 60, more de-
tailed photographs are shown in the November 1962 monthly report.
The optical bench was so useful that a second bench was built for use in
the field. The past year's experience has proven the value of having this
capability at the operating site as long as the overall system is under develop-
ment.
4. 3 Detail Correlator
A special purpose correlator was built to provide emergency backup for
the Processor and provide a special test capability. The original plan was
to use a horizontal liquid platen with a bent optical path. Many designs for
a vertical liquid platen with leak-proof film slots were studied, but none
seemed promising. The advantage of a straight path was finally achieved
by making a vertical platen with two large tanks so that the entire reel is
submerged. This is cumbersome, but it works and is relatively inexpensive.
The straight horizontal path allowed the use of the optical bench for a frame.
The same riders as were used on the previous bench were modified slightly
to provide for precision tilt adjustments.
This correlator has a 9 inch output image when using white light, so a
special camera was made. Various devices have been added to facilitate the
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experimental work. Photographs of the correlator are shown in Figs. 8 to
14. This unit uses the same optical system as the Processor, these items
were the spares for the Processor.
The 110 amp high intensity carbon arc and the condenser system which
focuses the arc onto the input slit is shown at the right of Fig. 8. In Fig. 9
the light shield has been removed and the alternate light source, a 1 mw
laser is in position. At the left end of the laser a 12 :mm focal length lens
focuses the beam onto the slit, thus insuring the optical adjustment of the
correlator with either light source. A larger laser has been found to be
very useful in cutting exposure times it can be inserted with the aid of a
mirror. Some of the slit mechanism is just visible to the left of the laser.
A shutter (with remote control) is mounted separate from the slit to avoid
vibration.
The collimator lens and liquid platen are shown in Fig. 10. The colli-
mator is an f/4 achromatic triplit with a 24 inch focal length. The liquid
platen holds the film immersed in tetrachlorethelene between two optical
flats. The reels are located in each tank and the film can be positioned in
range by raising or lowering the reels. The film can be advanced from the
observer's position (at the left in Fig. 8) by the variable speed motor. This
film drive is not intended for continuous exposure, but only to bring the image
of interest into position.
The platen can be aligned perpendicular to the optical axis, and can be
rotated around the optical axis to eliminate tilt between the data. film and
correlator (cylinder lenses and slit). This later adjustment can be made
from the operator's position by rotating the tube running along the side of
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Figure 8
Overall View of Bench Correlator
The optical system of the Processor is layed out along a straight line. The
film in the platen is advanced with the motor controlled by the box at the ex-
treme left. The range is adjusted by lifting the reels (inside the tanks). The
tilt is adjusted by a cam on the liquid platen assembly and is controlled by
the knob indicated. The zero stop is adjusted with the four cables leading
from the camera position. These adjustments are normally made while
viewing the output image with a microscope in place of the camera.
1. Light source - 110 amp theater carbon arc
2. Condenser assembly
3. Input slit assembly
4. Shutter
5. Collimator
6. Input film advance mechanism
7. Input film
8. Liquid platen
9. Field lens
10. Relay lens and zero stop
11. Cylinder lenses
12. Interference filter
13. Output film camera
14. Input film advance control
15. Liquid platen tilt control
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Figure 9
Laser Source on Bench Collimator
The 1 m watt Helium-Neon laser is inserted in place to illuminate the slit.
The laser light is focused onto the slit with a 12 mm focal length lens
mounted in the collar at the left end of the laser.
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Figure 10
Liquid Platen on Bench Correlator
The film is on 92 inch reels inside the tank. The film can be seen in and
above the tank window. The height (i. e. range) of the film is adjusted
with the graduated lift bar at the top. A pully and reversing motor ad-
vance the film. The platen can be adjusted in three rotational axies for
optical alignment and hologram tilt adjustment. The collimator lens is
seen in the foreground.
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Figure 11
Details of Rider Assemblies on Bench Correlator
The imaging section of the Bench Correlator as seen from behind the liquid
platen. The relay lens and "fixed" cylinder are in the foreground, the large
cylinder lens, camera, and film advance control box are in the rear. The
features are:
1. Zero stop adjustment micrometers.
2. Zero stop focus adjustment.
3. Lens board tilt adjustment (three per board).
4. Lens board height and tilt adjustment (two per board).
5. Lens board lateral adjustment.
6. Rider guide, 2 cylinders in groove on near side, pad on
flat on far side.
7. Rider lock down..
8. Bench alignment adjusting screws, the channel is adjusted
against the base H beam below.
9. Cylinder lens rotation adjustment micrometers.
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Figure 13
This camera views a full range width of output image. It normally records
about 3/4 inch in the azimuth direction.
1. Cylinder lens rotation adjustment.
2. Cylinder lens lateral adjustment.
3. Interference filter in mount.
4. Vertical position of interference filter.
5. Film supply (50 foot capacity).
6. Dark slide in front of film.
7. Film take-up.
8. Camera mount. This mount will also accept a
polaroid fixture.
9. Camera advance.
10. Platform for microscope.
11. Post to accept viewing mirror.
12. Liquid platen tilt adjustment.
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Figure 14
Output Image Viewing Accessories on Bench Correlator
The viewing devices used on the bench. It is shown setup for making 5X en-
largements.
1.
450 mirror and viewing screen in position. It can be
swung around to photograph the image.
2.
Mount for 35 mm camera.
3.
Microscope.
4.
Lateral adjustment.
5.
Focus adjustment.
6.
Vertical fine adjustment.
7.
180 mm projection lens mounted so as to have adjust-
ments 4, 5 and 6.
8.
4 x 5 film holder.
9.
Polaroid sheet film back.
10.
Shutter release.
11.
Liquid platen tilt adjustment.
12.
Input film advance.
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the bench.
The field lens is similar to the collimator lens and can be seen near the
platen in Fig. 8.
The relay lens images the range information onto the camera. It is a
duplicate of the f/8, 16 inch focal length lens used in the Processor. The
zero order stop or spatial frequency cut-off filter is located inside the lens,
and is adjusted by the two micrometers shown in Fig. 11. For bench use the
remote adjustment has been found very helpful. The :relay lens was modified
slightly so that the aperture weighting filters could be inserted behind the zero
stop as shown in Fig. 12.
Two cylinder lenses are used to refocus the azimuth image. The first is
located just behind the relay lens, the rotation adjustment can be seen in Fig.
11. The second lens is mounted further back, and is moved along the bench
to achieve azimuth focus. The rotation and cross-slide adjustments can be
seen in Fig. 13.
The 35 mm camera is also shown in Fig. 13. The camera has an aper-
ture of 1 x 9 inches. Fifty feet of film is stored in the lower magazine and
can be advanced by the crank into the camera and take-up magazine. The
camera has a dark slide, but no shutter. For white light operation, the
wedge interference filter is inserted in the holder mounted on the front of
the camera.
The 35 mm camera can be displaced and the image observed on a ground
glass, with a hand magnifier or with the microscope shown in Fig. 14. An
alternate assembly will take 4 x 5 plate holders, a Linhoff 70 mm film back
or a 4 x 5 polaroid film back. As shown in Fig. 14 the image can also be
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projected back onto the 4 x 5 film holder with a projection lens. The lens is
usually tilted to match the range focus variation of the holograms on the input
film .
This unit has been used continuously for the past year, and most correla-
tions in this report that are not from the Processor were made on it. In addi-
tion Testinghouse personnel have used it from time to time. A similar
unit, using available lenses, has been built for Westinghouse in 1965.
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5. 0 DATA SIMULATION
The Processor normally uses data from a coherent side-looking radar
system as an integral part of its optical system. Very little meaningful work
can be done on the Processor without that data or simulated data. For this
reason, the first step was to generate a pattern which would simulate that
data. This section describes the simulated patterns made on the project.
5. 1 Requirements
The data produced by the radar is an overlayed complex of dots on a
photographic film as is shown in Fig. 3. Each point in the scene gives rise
to an exposed line lying along the azimuth direction. This line varies in
transmission along its length in a specific fashion as determined by the
physics of the radar situation , such that
V1 = T 0 + A sin kx2
where T is the film transmission, To is a nominal transmission, A is re-
lated to the modulation, x is distance along the film, and k is a constant
for one pattern dependent on the parameters in the radar system. This
variation is commonly characterized by electronic engineers as a linear
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FM (frequency modulation) signal, and it is described by optical engineers
as a slice of a zone plate. The data film obtained by flying past an ordinary
complex scene is a composite of many such individual patterns.
5.2 Pattern Types and Techniques
A number of patterns and pattern arrays can be simulated. Single pat-
terns can be drafted or ruled on machines to generate "square wave" patterns,
i. e. those having only two transmission levels. These can be photographically
reproduced to obtain any scale factor or "focal length" desired by changing the
effective value of k. They could also be reproduced in a limited resolution
system or a system using spatial filters in the diffraction plane to produce
approximate sine wave transmission. Single patterns could be generated by
recording suitable interference patterns (such as Newton's Rings). The pat-
tern could also be generated by moving film past a narrow light source which
changes in intensity in a controlled fashion (the method actually used in the
recorder sub-system of the radar unit).
A single pattern can also be simulated in a different sense by using a
cylinder lens at the position of the data film.
Multiple patterns for specific purposes can be made by multiple printing
single patterns onto a single photographic film. This technique has certain
limitations, particularly the fact that the incoherent summation of exposures
in overlapped patterns instead of adding radar phases gives rise to distortions
in the array.
Multiple patterns could also be generated by adding phases in an inter-
ferometer system, or computing complex signals to modulate a light source
in the moving film technique. These techniques could also be utilized to
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make an array simulating a continuous tone scene.
Most of the techniques mentioned have been investigated. The single
square wave target has been made and is discussed in the following section.
Some patterns were obtained using interference techniques during a study
phase in 1960, but the capability of the system was limited and it was not
pursued at the time. Later interest in interference techniques centered
about continuous tone array simulation. A number of techniques are feasible,
but difficult (and therefore, expensive) and were not formally proposed or
pursued on this project, partly because it was anticipated that FlOl flight
test film would fulfill the need for such pattern arrays. However, this tech-
nique was pursued on an in-house project as is described at the end of this
section.
The techniques of modulating a light source and moving film was inves-
tigated and proposed. A fast digital computer was to be used to modulate a
cathode ray tube in one of the recorders built for the radar system. This
technique has the disadvantage that the limitations of certain computer
functions would preclude generating a continuous tone array, and the tech-
nique would inherently include the recorder and its problems in the resultant
data. After further considerations, this technique was dropped from the
proposal. However, later testing on the recorder program has resulted in
swept FM patterns being generated for some test purposes, and these pat-
terns have been used for some tests.
Some of the work has raised questions which could best be investigated
with a cylinder lens pattern simulation. Such a lens was fabricated and used,
but it was not feasible to test it adequately to justify its use as a test device.
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5. 3 Ruled Pattern Manufacture
All of the simulated targets which have been used to test the Processor
have been made by using a ruled pattern. This was accomplished by first
making some test rulings and photographing them to establish optimum
parameters for the master. One of these test rulings was used to make
the 24 inch focal length patterns used for the 1961 acceptance test. The
next step was to program the formulation of a pattern on a Royal-MacBee
computer to printout the 3000 necessary settings without error. The data
results from the equation
x= V-1:0: + .0018
where + is used if n is even, - if n is odd. n is a running integer, x is the
coordinatograph setting, and . 0018 is the effective half width of the scribing
diamond.
The ruling was done on the Haag-Streit coordinatograph, a precision
measuring and ruling device shown in Fig. 15. The master was then contact
printed to give film sub-masters. These were reduced photographically in
precision reticle cameras to the scale factor desired. An array of sub-
masters and the resulting scaled masters are shown in Fig. 16. These
scaled masters were then contact printed to give the patterns and pattern
arrays used in the Processor.
The first patterns used were on small pieces of film which were conven-
ient for static tests. Later the master was mounted in a precision repeating
printer known as a Misomax, and pattern arrays with accurately controlled
overlaps and locations were made on 9 a inch wide film. As the capability of
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Figure 15
Ruling the Master Zone Plate
The master zone plate is shown on the table of the Haag-Streit Coordinato-
graph. The ruling diamond is in position on the master. The individual
settings were accurate to . 0003 inch.
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Figure 16
Zone Plate Sub-masters
The master was contact printed onto high resolution film. These sub-
masters were then reduced to the size shown above.
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the Processor and Bench Correlator improved, better targets were needed
and were made.
The phase accuracy of the targets has been a prime goal. The master
was ruled to an accuracy of better than . 001 inch at each point over its 20
inch length. Glass was used as a substrate to preserve this accuracy. In
the sub-masters overall shrinkage only alters the scale factor and differ-
ential shrinkage is less than . 001 inch. The optical reduction process must
be carefully implemented if harmful distortions are to be avoided, so reduc-
tion was done on a precision camera with a low distortion lens. The reduced
pattern was checked on a Mann Comparitor and found to be quite good. The
latest series of targets were accurate to better than ;4 cycle of the highest
frequency. These were used to make the precision targets T150 and T160.
The test films which have been made are listed in Table 4 and Table 5.
Table 6 describes T115 in further detail. Some photographs showing some
examples of these patterns are shown in Figs. 17, 18 and 19. Overlapped
arrays consisting of 2 and 5 patterns have been made with a wide range of
separation. An attempt was made to overlap 30 patterns, but the sensito-
metric problems of dealing with many very weak exposures prevented any
useful results. Some patterns were printed on grainy film to simulate noise.
5. 4 Continuous Tone Data Simulation
The continuous tone data that has been used has come from the F101
Flight Test program. None of this data. is perfect, nor is any of it accurately
defined as to frequency content, linearity, modulation, or a host of other
factors. However, it has been very helpful in working with the Processor.
No attempt will be made to describe it separately here, and the reader is
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T-3 24 inch for 3 colors
T-4 Gurly long-lines range test target
T-5 150 inch and 200 inch singles
T-6* Aerial Photo Boston
T-7 24 inch
T-8 24 inch three colors positioned on 9i inch film
T-9 200 inch . 001 wide
T-10 150 inch . 001 wide single
T-11 140 inch . 001 wide various densities
T-12 150 inch two inch wide paste up area
T-20 Long line 66, 88, 110 1/mm
T-21 Long line 40 1/mm
T-22 Long line 32 1/mm
T-23 Long line 24 1/mm
T-24 Long line 72, 96, 120 1/mm
T-1 * Standard Air Force resolution target good to 6-6 group
T-2 24 inch overlapped
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Single Targets Suitable for Static Testing
Various 150 inch and 200 inch targets
Indicates test films which are not "patterns. "
The figures refer to the focal length of the pattern in green
( A = 550 or 546. 1) light.
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Table 5
Targets Exposed on Long Lengths of 92 Inch Wide Film
T101 scribed every 3 feet
T102 grid and resolution for clocks positive
T103 grid and resolution for clocks negative
T104 200 inch non squint . 001 inch wide
T105 200 inch squint . 001 wide overlapped
T106 200 inch non squint overlapped
T107 150 inch squint . 001 inch wide various densities
T108 150 inch squint . 001 inch wide overlap
T109 200 inch dot low
Tl10 200 inch dot medium
Till 200 inch dot double overlap high density . 010 to . 001
T112 200 inch dot double overlap very high density . 101 to .001 sep.
T113 200 inch dot 5 overlap low density .060, . 045, . 030, . 015, . 000
T114 200 inch dot 5 overlap high density . 060, . 045, . 030, . 015, . 000
T115 150 inch squinted double and 5 overlap high, medium, and low density
T116 150 inch squinted noisy double and 5 overlap high, medium, and low
density
T117 200 inch non squint as T115
T118 200 inch squint as T115
T119 150 inch non squint as T115
T120 150 inch squint 71 patterns evenly spaced
T150 150 inch squinted pairs, high, medium and low density
T151 200 inch squinted pairs, high, medium and low density
T152 150 inch squinted pairs, high low and low high. overlapped
T153 200 inch squinted pairs, high low and low high. overlapped
T154 near range, 3 color overlapped
T155 far range, 3 color overlapped
T156 150 inch squinted and overlapped, 016 separation
T157 140 inch squinted pairs, . 001 wide as T150
T158 200 inch squinted pairs, . 001 wide as T150
T200 series. Copies of any of the T100 series.
Indicates test films which are not "patterns. "
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Parameters of Test Pattern T115
Test Film
T115
Patterns
Per Set
Sets
Per Series
Density
Pattern Separation
(inches)
Series I
2
12
both high
. 000, . 040, . 036,
.028, .024, .016,
.012, .008, .004,
.000,
Series II
2
12
both medium
same as series I
Series III
2
12
both low
same as series I
Series IV
5
5
all high
.060, .045, . 030,
.015, .000
Series V
5
5
all low
same as series IV
Series VI
2
12
high-low
same as series I
Series VII
2
12
low-high
same as series I
Single pattern for line width test.
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RM111"MMIMM"11
" uilYlu~u~i~
IIIIII IIIIIII
III
a. portion of the master
b. 200 inch focal length squinted
c. 150 inch focal length squinted
d. 150 inch focal length entire pattern
11111111
1111111111111111
h tdc.t1 h-1-101
Figure 17
Full Scale Prints of Zone Plates
The lines along the length of the pattern were scribed so as to be per-
pecidicular to the main rulings. The two central lines are reproduced
on all patterns for tilt and range checks.
111111111111111111111111
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VI _v Ir-%L_ I IP%IVLJL_Ir__tJ
INIII# IIIlIIIIIIIIIIIIIIII
1111111111111111111
110110 INN
IIIIIIIIIIIIIIIIIIIIIIIIIIIIII IIIIlII'
Figure 18
Overlapped Zone Plates
Each of these are made by double printing a sub-master with a shift
between printing. The shift is approximately . 002" (top), . 010" (center),
and . 080" (lower). Note the Morie banding.
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Figure 19
The targets are printed in precise registration on a. roll of 9; inch film
for use in the Processor. A section of test film T115 is shown.
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referred to Section 8. 3 where the overall flight program results are discussed.
Throughout the program the possibility of making, continuous tone simu-
lated data was considered. A number of techniques were studied; but each
required expensive equipment and considerable project time to obtain usable
results. Early in 1963 a new light source, the helium-neon laser, became a
practical tool and reduced considerably the effort required for most interfer-
ence experiments. At that time Itek sponsored an in-house project to make
holograms and generate synthetic data suitable for the 9015 Processor. The
research report is contained in Appendix VIII.
To simulate radar data for this system a hologram with the following
special characteristics is required:
(1)
(2)
Dispersion is required only in the azimuth dimension,
with normal imaging in the range dimension. (This is
not the case with a chirp system, but even here the
dispersion is different in the two dimensions, requiring
an astigmatic system. )
The offset or squint angle and the hologram spatial fre-
quency bandwidth must be constant.
(3) A large azimuth stretch-out of about 8:1 must be pro-
vided.
(4) The hologram focal length is very long, approximately
150 inches.
None of these requirements are met with the conventional method of
hologram generation so a specially designed astigmatic optical system,
described in some detail in Appendix VIII, was constructed.
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These holograms were of constant focal length and therefore would have
been in focus at only one range interval in the optical processor.
The optical generation of holograms with variable focal length across the
range dimension is a more difficult problem. With the constraint that input
and output film planes be flat, it is found that the focal length resulting from
tilting input and output planes is not a linear function of distance off axis,
but contains quadratic and cubic terms. By suitable design, these terms can
be held to a negligible value, but it was found that the azimuth: range stretch-
out ratio could not simultaneously be held at the required value. These prob-
lems could have been solved or circumvented with additional project effort.
The combination of F101 films and test targets were good enough so that the
additional work was not warranted.
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TEST PROGRAM
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The Processor and bench correlator have been in use continuously since
they were built. Most of the work has contributed to a better understanding
of the Processor, the correlation process, and the coherent radar system.
A Processor test program was initiated in 1962. The testing has continued
throughout the program and is intertwined with the modifications, FlOl data
processing, and studies performed. The specific test directed toward Pro-
cessor performance is discussed in this section. All of the topics originally
proposed in the Test and Simulation program are discussed.
6. 1 Resolution in Range
In the range dimension the Processor is similar to an ordinary 2X en-
larger except for some details which should only have a secondary effect on
the resolution. For this reason an "ordinary" resolution target of lines and
spaces is adequate. This is placed in the platen with the lines running in the
azimuth direction, and the resulting image observed or photographed at the
output image plane.
The optical system of the Processor must be modified by removing or
misaligning the zero order stop since there is no azimuth detail to diffract
any light past that stop. This should not have any effect on the applicability
of the test data, and some of the tests verify this assumption qualitatively.
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The correlator optical system is illuminated in a very special fashion,
with highly collimated light in azimuth. This leads to diffraction effects
which tend to make the images complex and interpretation difficult. An at-
tempt to eliminate this problem and to measure range resolution. by illumi-
nating the platen with incoherent light gave very low resolution readings
(only a few lines per mm). Much of this loss was traced to the spatially
incoherent illumination. The 4 element relay lens was designed with ray
trace data from rays that will actually exist in the Processor. As a result
the aberrations are not controlled for all possible rays passing through. any
part of the aperture. Tests on a lens bench, without the cylinder lenses,
indicated that a diffusely illuminated target gave very low resolution, but
that good resolution was attained when the optical path was baffled to limit
the rays to those anticipated in the Processor. A resolution of 65 * 1/mm
on axis and 45 1/mm at the edge of the field was obtained using a standard
3 line Air Force Resolution Test Chart. The addition of flat glass to simu-
late the platen and cylinder lens glass thickness made no noticeable changes
in the image.
The lens bench tests were repeated in the Processor with the aid of this
new knowledge. Visual results of 60 1/mm on axis anc. 40 1/mm off axis
were noted, but the data is questionable since the effects of diffraction and
spurious out of focus images could not be avoided or evaluated. Photog-
graphic tests were experimentally difficult, and did not achieve resolution
of better than 20 1/mm.
All resolutions are referred to the output or map film.
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In February of 1963, the long line range resolution tests were rerun
with the better cylinder lenses. At this time, it was realized that the
limited aperture, especially when the zero order slit was in place, pre-
vented the diffracted energy from high frequency targets from getting to
the image. The tests were changed from measurements of the smallest
resolvable line spacing to a measure of the contrast at a nominal line
spacing. An enlargement of the results of a photographic test at 20 1/mm
is shown in Fig. 20. The contrast on the originals was 58% on axis and
35% off axis. This would indicate a half power width of . 0007" on axis
and . 0011" off axis.
A second method used to check range resolution was to observe the
image formed by a line . 002 inch wide scribed along each edge of the pat-
terns (see Fig. 17). When this image is correlated this line should leave
a .004 inch gap in the resulting image. (For example, see Fig. 22 below.)
This has not been accurately assessed quantitatively, 'Dut it has maintained
a check on the range performance and has the advantage that it is obtained
while the system is working in its correct alignment.
Another check on range resolution is obtained by processing; a pattern
which is approximately .001 inch wide and should give an image about . 002
inch wide in range. Attempts to obtain good point images with the old cylin-
der lenses led to poor results in azimuth, but range image width of about
.003 inch were obtained as shown in Fig. 21. This technique was experi-
mentally difficult, and has not been pursued further.
The range resolution has also been measured by inserting a film with
a set of very narrow (. 000211) clear lines running the length of the film.
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Figure 20
Range Resolution Test Image
This is an enlargement (40X) of a photographic image made to test range
resolution. A long line square wave target was placed in the input platen
of the Processor and this image was recorded at the output. The original
photograph was measured on a microdensitometer to determine the contrast.
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Figure 21
Dot Images
This is an enlargement (approximately 10X) of a rLumber of dot images.
The input zone plate pattern was approximately . 001 inch wide and it
should ideally correlate to a short line . 002 inch long in the range
direction. In this photograph the azimuth (horizontal) length is rela-
tively long, but the range spread is . 003 inch or less, indicating good
range resolution. The dots shown vary in exposure.
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These would form a set of geometrically ideal lines . 0004" wide on the out-
put. The image was recorded on Royal-X Recording film and the test was
run with the films driving at normal speed. The measurement gave line
width of .001211 on axis. The lines near the edge of the field were not
measured, but they appeared to be only slightly wider.
6. 2 Image Size in Azimuth
The width measurements have been made on line images formed by pat-
terns shown in Fig. 17. The first correlated images obtained in November
1961 were observed visually and judged to be diffraction limited (the pattern
was relatively short). The images were not photographed, so that data could
not be analized and carefully interpreted. Data obtained in May 1962 gave
line widths of . 005 inch to .006 inch in many runs, both static and dynamic.
Further tests and observations made during the flight test support work con-
tinued to give about the same performance.
In November 1962, the new cylinder lenses were installed and the line
width tests were resumed. Some preliminary line widths of . 003 inch width
were obtained under idealized conditions (the aperture of the pattern was re-
duced to give optimum results). The best data obtained during that period
was that obtained in February 1963. This gave a line width of . 002 inch with
a medium width (15,) slit and a 0. 4% bandwidth interference filter. An en-
largement of the image and a microphotometer trace of one line is shown in
Figs. 22 and 23. Attempts to narrow the line below a . 002 inch width lead
to a critical examination of the test target. The target was found to have
some phase error, and new targets were made. By 1963 it had been es-
tablished that image separation was a dependable method of measuring test
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Figure 22
Azimuth Line_Ima e
This is an enlargement (35X) of an image formed by two overlapped patterns
as shown in Fig. 18. The two lines are separated by . 007 inch in azimuth.
The breaks in the lines are the range check lines. They appear tilted, this
would indicate that the pattern and cylinder lenses were misaligned by a few
minutes of arc. (This would have almost no effect on azimuth line width. )
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Figure 23
Microphotometer Trace of Fig. 22
This is a transmission trace of one of the lines shown in Fig. 22. The
trace was made with a microphotometer on the original negative.
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target resolution, and the later tests used this simpler technique as discussed
below.
6. 3 Azimuth Signal Separation
The separation of images of two simulated targets which are close to-
gether in azimuth was first tested in February 1962. Most of the patterns
used are double exposures of a single square wave test target as described
in Section 5. 3 and shown in Fig. 18. Images separated by . 0045 inch on the
output film were resolved with the 24 inch focal length system before the
Processor was converted to a 150" system. In November 1962, as soon
as the good 150" optics were installed, a separation of . 0027 inch was photo-
graphed and resolved. In February 1964, a laser was jury-rigged into the
main correlator between the input slit and the main condenser assembly.
The test pattern used on the bench was used here and again images separated
by 0. 0009" were well resolved visually and photographically, see Fig. 24(a).
New test targets were made with closer spacing and it was observed that the
azimuth resolution limit was between 0. 0007" and 0. 0009". A separation
of 0. 0008 inch represents approximately 4 feet separation of targets in
azimuth on the ground from flight test altitude.
Aside from bandwidth, there was no apparent reason why the correlator
could not do nearly as well with the carbon arc and the wedge filter so reso-
lution tests under these conditions were pursued again.. This time it was
possible to obtain, with the original targets, 0. 0009" image separation
visually, and 0. 0018" separation photographically, see Fig. 24(c). The
targets separated by 0. 0009" in image space could not be resolved photo-
graphically due to an effect that at first appeared to be vibration from the
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.0009 inch
.0007 inch
.0018 inch
separation
separation
separation
laser
laser
carbon arc
(a)
(b)
(c)
Figure 24
Azimuth Line Separation
These are three enlargements (100X) of tests made with overlapped
targets in the Processor.
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carbon arc. In subsequent tests with the laser it was discovered that air
turbulence in the region between the upper input platen and the input slit
was the source of the difficulty. The air turbulence was created by the
cabinet exhaust fan and was eliminated by inserting the light and dust
baffle around the upper platen. Resolution tests were not completed with
the carbon arc after this discovery because of necessity of preparing the
correlator for shipment. If was felt, however, that target separation of
less than 0. 0009" in the image plane could be photographed using the car-
bon arc and wedge filter once the problem has been identified and corrected.
Some tests were run with 5 overlapped patterns. The sensitometry of
the pattern making process becomes much more complex. Film inertia,
reciprocity law failure, pre-exposure, and post-exposure effects combine
to cast considerable doubt as to the exact nature of the resulting pattern
array. The pattern does create five images although not as good a sepa-
ration nor with equal image intensities.
6. 4 Focal Length Compensation
This test was intended to demonstrate that the wedge interference filter
technique would compensate for the variation of pattern focal length with
range. The test was envisioned before the Processor had correlated any
data film and was designed to (a) prove and demonstrate that wavelength
compensation works, and (b) uncover any unsuspected problems associated
with wavelength compensation. A series of three targets were made for
the 24 inch focal length system and checked visually in December 1961.
This test showed qualitatively that the focal length variation was corrected,
but the results were not quantitatively conclusive and photographic records
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were not obtained.
In February 1962, some slightly different tests were recorded which
demonstrated that the image does go through focus when the wavelength is
changed. The results are shown in Fig. 25. At that time the quantitative
interpretation of the data was poor due to the cylinder lens problem. By
the time good cylinder lenses were installed the wavelength compensation
had been adequately demonstrated with F101 film and this experiment was
not pressed further.
6. 5 Pattern Tilt
This test was intended to verify the theoretical finding that the azimuth
line width and range resolution would be sensitive to tilt angle misalignments
on one minute of arc. It was expected that this sensitivity would not be ex-
perienced until the Processor was performing to its full optical capability.
Experience on the Processor verified these expectations. It was found
that angular rotations could usually be readjusted to within 3 to 5 minutes
of arc by observing the two range resolution marks on the line images (see
Fig. 22). A visual test run in April 1962 to determine the effect on line
width gave a noticeable spreading with a 5 minute misalignment. The tests
using dot patterns described in the range resolution section above required
that the alignment be within 10 or 15 minutes of arc before the image could
be even found in the image plane. Recent experience has indicated that the
better resolution obtained with the good cylinder lenses does demonstrate
increased sensitivity, one test showed image degradation with a 3 minute
of arc misalignment.
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Figure 25
Effects of Wavelength Variation
These are three enlargements (13X) of a single pattern exposed with the
wedge inteference filter shifted. At the left the filter is correctly posi-
tioned near the upper end of the line. The effect of wavelength variation
along the wedge filter can be noticed. In the other two exposures the fil-
ter has been shifted as indicated. The wavelength shift is larger at the
upper end of each of these exposures.
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6. 6 Effects of Pattern Focal Length Variations
This test was intended to check the depth of focus of the instrument and
determine the image deterioration with focus errors. The primary purpose
of the test was to obtain data to assist in developing focus control techniques.
The depth of focus has usually been found to be very large. In January
1962, the depth of focus for the 24 inch focal length system was found to be
+ . 030 inch. The 150 inch system with poor cylinder lenses usually was in-
sensitive to focal shifts of + . 050 inch or more. Recent tests have shown a
depth of focus of + .015 inch for range and + .025 inch for azimuth. The
tests indicated that special focusing techniques would not be needed for the
9015 Processor. Later experience and knowledge has verified this conclu-
sion.
6. 7 Signal Integration
This test was intended to study some of the noise effects and signal to
noise improvements to be expected in the Processor. These tests were in-
tended to be run after most of the other tests were completed. Some pre-
liminary tests were made in 1963 with a grainy input: target. The noise
had very little effect on the pattern obtained.
No further specific tests have been performed on this problem. Late
in 1964 the bench correlator, Processor, theory, and F101 film quality
were perfected to the point that meaningful work could be started, but no
conclusive results have been obtained as yet. See also Section 7.8.
6.8 Moving Film Tests
The film drive must meet very rigid requirements in the Processor.
It was found to be very difficult to test the film drive: in any test other than
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to run film in the Processor. The final proof of adequacy of the drive was
to be accomplished by comparing static and dynamic runs of the same target.
Even this test is actually fairly difficult since the tilt angle of the target
changes when the film comes to rest for a static test. General experience
has indicated that the results of static tests can be repeated dynamically
after the tilt and drive ratio adjustments are optimized. A series of test
runs in May 1962 show no difference in static and dynamic tests, and a later
check in November showed no measurable image smearing on .003 inch wide
line s.
Tests made on the new drive system in 1963 indicated that the long time
average (a number of revolutions of the drive roller) could be set and main-
tained to an accuracy of 0. 03%. Various tests designed to determine film
slippage and/or short term drive ratio variations were conducted. These
tests indicated no such problems, but it must be pointed out that these tests
were only sensitive enough to detect problems of 1% error or larger. Con-
tinued usage of the Processor has not indicated any short term variation of
the drive speed or drive ratio.
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STUDIES
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7.0 STUDIES
A number of theoretical and experimental studies were made during the
four years. Most of these studies were directed toward obtaining solutions
or answers to specific problems rather than toward the gathering of theore-
tical or experimental data.
This chapter discusses many of these studies which required extensive
time and/or may be of lasting interest. In some cases additional technical
information is included as an Appendix.
7. 1 Early Experimental Work
The first task was to set up an optical system to verify the assumption
made in and establish an experimental base upon which to
build the detailed design. The optical bench described in Section 4. 1 was
designed and built. Some hand drawn targets and some targets
were successfully correlated in October 1960 (see Fig. 26). It be-
came clear that high quality input data would be required for quantitative
tests. Such data can be generated by a number of interference techniques,
and a modified Twyman-Green Interferometer was set up to generate test
patterns. The proper patterns were observed, but attempts to obtain ade-
quate photographic recordings of the pattern indicated the need for better
equipment and more time than was available.
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Figure 26
Results of First Correlator Experiments
These results were obtained in late 1960. The input patterns are shown
above, the correlated images are shown in the center photograph. There
was no range imaging in the system. The lower photograph has a cylinder
lens to focus range. The images are the bright sections, the zero order
and virtual image light spreads into the background seen.
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Original Patterns Generated on CRT
Unfiltered Images Reconstructed with Cylindrical Lens
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The experimentation on the bench with the crude targets available con-
firmed most of the concepts and gave experimental back-up for quantitative
theoretical work. A specific example of the value of the bench was the dis-
covery of the data film alignment problem discussed in Section IV(D) of the
Processor Final Report and in Section 6.5 of this report.
7. 2 Non-Optical Tests
Many tests were performed on portions of the Processor which do not
relate directly to its ability to correlate radar data. These included tests
on film drives, the optical mounts, the data clock transfer equipment, the
carbon arc, and a host of other items. Most of these tests were of transient
interest only and are not discussed here. Three of these tests which are
still of interest or which played a key roll in the program are discussed
briefly.
7. 2. 1 Mirror Mount
The mounts for the optical elements utilized adjusting techniques which
were intended to maintain the adjustment permanently without the use of
locking devices. This basic technique was incorporated into a mirror angle
adjustment device which used a stiff spring to hold the mirror cell against
the adjustment screw. This equipment was breadboarded with aluminum
plates and checked with a theodolite. Some modifications were found neces-
sary to eliminate interactions between motions around the two axis. The
unit was built* with this design and has performed excellently.
A photo is shown in the Processor report on page 12 and Instruction Manual
pages 3-23.
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7. 2. 2 Liquid Platen
A test was performed on the liquid platen to obtain information about
bubble control and determine the properties of suitable liquids. This test
was very helpful and the recommendations still hold. The test report, in-
cluded as Appendix II, gives a good description of the test results.
7. 2. 3 Film Drive
A complex breadboard was built to test the film drive. This unit was
designed to drive two 92" films through suitable rollers with the rubber
wheel drive. This unit proved out the basic technique even though it was
impossible to devise feasible testing techniques sensitive enough to check
the mock-up to full accuracy.
The engineers used the mock-up primarily to check their initial deci-
sions as to bearing sizes, rubber thickness, etc. This unit was used later
in testing modifications to the Processor film drives and also to support
some tests on the recorder program. In 1963 another simpler mock-up
was made to obtain quanatative analysis of the rubber wheel action, this
is discussed in the Processor Final Report on page 45.
7. 3 Bandwidth and Aperture Weighting
The signal-to-noise ratio and diffraction ring ("side lobe") suppression
of an aperture-limited system can often be improved by use of aperture
weighting. In the case of the 9015 detail correlator we are interested in
weighting both azimuth and range, for extraneous light appears from both
dimensions. Since the spatial frequency spectrum of each will be different,
an elliptical rather than a circular filter will be necessary. In practice,
however, two one-dimensional filters will be placed in quadrature.
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The investigations were begun about a year ago. The first finding was
that photographic film, on which the filters were made, was insufficiently
flat, and impaired the resolution of the relay lens. Obviously optical-quality
glass was required for the filter. Another difficulty arose from the granu-
larity of the photographic emulsion, which tended to scatter too much light.
Deposited aluminum filters were chosen finally because they offer much
better scattering characteristics, although such filters are more difficult
to fabricate.
The varying transmission is obtained by depositing the aluminum through
a narrow slit which oscillates in front of the surface to be coated. Gradations
in density are controlled by the velocity of the slit, since the evaporation rate
is constant. A cam of a certain profile is required to drive the slit in the pro-
per manner. Appendix VII explains the process by which the proper cam pro-
file was designed. The cam operates through a linkage which could be adjusted
for any desired bandwidth. Unfortunately there was no way of monitoring the
deposition while it was in progress, so a trial-and-error method was used.
The transmission curve of each filter was traced on a microdensitometer,
and the proper correction applied to the next deposition.
Eventually the set of filters seen in Fig. 12 were fabricated. These have
approximate bandwidths of 125, 250, 375, and 500 cycles per inch when used
on the bench correlator. Filtering in the range direction was foregone for
the time being.
7. 4 Moving Targets
The detection of moving targets is not a prime function of the radar
system, but since the inception of the program it has been thought that
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moving targets could be located. Certainly the necessary information has
been on the data film, for the entire doppler history of a target is recorded
while it is in the antenna beam. Not until 1964, however, was a moving tar-
get recognized. The detailed theory to determine ambiguity effects and sen-
sitivity has not been investigated, but the following information is of interest.
Several photographs were taken of this target and of other targets sub-
sequently recognized. An investigation of the relevant mathematics was
made, the result of which is the report that is Appendix VI. Basically, tar-
get motion in azimuth (i.e. parallel path) yields a correlation focal-length
different from the environment; and target motion in range results in an
azimuth-displaced correlation. A detail correlator can be calibrated so that
the velocity components can be readily measured, and a method of so doing
is included in the appendix.
A single example will demonstrate the principle. The photographs in
Fig. 27 are from film S53. The four shots represent a 3-inch range of focus.
In (c) the background seems to be sharpest, while on the highways there are
three returns which are out of focus; these are labeled. 1, 2, and 3. Note
that target 1 is in focus in (a), but blurred on the other three photographs.
Similarly target 2 is in focus in (b), and target 3 is in focus in (d).
An attempt was made to measure the parallel velocity components of
these targets. The detail correlator was calibrated as suggested in Appen-
dix VI, and the appropriate graphs were constructed. The resulting esti-
mates are as follows:
Target 1: 66 mph
Target 2: 33 mph
Target 3: 33 mph in the opposite direction.
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This is all very approximate, and there is unfortunately no way of verifying
the accuracy of the results; but they do seem to be reasonable speeds for
cars.
The determination of the perpendicular or range velocity is more diffi-
cult. In the 9015 system there are two restrictions on the determination of the
range velocity components. The first is associated with PRF of the system,
which is 4000 cycles. There will be an ambiguity unless the Doppler shift is
less than 2000 cycles. The velocity can be found from the relation
2V
my <
2000
r
V
2 2 0
mi.
(
0671)
my
.
r
.
Vmy <
66 mph.
for unambiguous determination.
The second restriction is more limiting. The bandwidth limitation in
the recorder is limited to about 1000 cycles, and an intentional offset of
about 300 cycles is used, so a doppler range of minus 1300 to plus 700
cycles can be recorded. This limits the radial velocity to a range of -43
mph to +23 mph.
7. 5 Image Analysis
The map films made from the F101 test flights have contained poorer
images than were expected. In 1962 and much of 196:3 this was largely
due to poor system performance, but by early 1964 it became obvious that
the lack of image interpretability was not due only to inadequate resolution.
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Resolution of 20 feet had been demonstrated, and azimuth resolution was sus-
pected to be half of that, yet no aircraft and few other objects of 100 foot
dimensions were recognizable. City and industrial complexes showed much
strong return but individual buildings usually were not evident. A major
problem limiting the usability of the output map films was and still is that of
interpreting the images on the map. The overall process can be considered
in a number of steps:
(1) The actual reflection characteristics of a target.
(2) The reproduction of that reflection characteristic
on the map film.
(3) The interpretation of the image pattern as the on--
ginal target.
During 1964 this problem received considerable attention. Topographic
maps covering much of the area flown over were procured, and large scale
aerial photographs of much of the area were purchased. All useful flights
up to S125 were plotted on map overlay sheets and keyed to the topological
maps and aerial photos. Some of the facilities are shown in Fig. 28.
In general, it was found that at small scales (1" == 2 miles) the radar
picture appears similar to an aerial photograph as illustrated in Fig. 29. At
larger scales (1" = i mile) the typical differences between the two sensors
show up, but the radar picture can still be thought of as an "unusual" photo-
graph. At a scale large enough (1" = 1, 000 feet) to show the smallest re-
solvable element, the radar photo bears little resemblance to an aerial
photograph. The illumination, wavelength, and reflection characteristics
are now entirely different. In many regions spurious images now dominate
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the contrast is about the same as is seen in Fig. 4).
The difference in the dock area and corner reflector test may be due to
the two flights, but it is typical of all experience. Single targets, or well
known and simple targets seldom give trouble in determining best focus,
while complex targets are confusing and the operator of the correlator is
never sure which image pattern is "correct. " It should be pointed out that
this is the situation as of the end of 1964, it may not be true after further
improvements in the equipment or operating procedures are made.
7. 6 Color Bandwidth Correction
The optical correlation process is a diffraction phenomena and therefore
should ideally be done with monochromatic light. In the 9015 Processor this
requirement is approximated by using a narrow band interference filter with
a white light source. This creates a spreading of the image due to the fact
that the light which is not at the center of the pass band generates out of
focus images. The filter was specified to have a very narrow pass band
(about 5 mom) to keep this defocusing effect as small as possible? The pure
longitudinal defocusing is adequately small for the system at present.
The wavelength variation also gives rise to a lateral image shift due to
the fact that the hologram is squinted (see Fig. 17). This shift causes a
large portion of the loss in resolution. This shift can be eliminated in
principal by dispersing the input collimated beam a corresponding amount.
A study program was initiated late in 1962 to investigate methods of dis-
persing the beam in the Processor. A technical report on that study is
included in Appendix III. The first effort concentrated on finding optical
glass combinations which would give a uniform dispersion across the visible
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spectrum. It was found that the dispersion would vary by a factor of two or
more with any reasonable prism, and the basic configuration of the Processor
would have to be changed to accommodate the new optical path.
The next step in the study was to investigate a diffraction grating. It
was possible to design a grating which would replace the lower mirror, but
the question of grating efficiency and the displacement of the output image
were open questions. A grating was designed and ordered from the Bausch
& Lomb Optical Company. Further analysis indicated. that the zero order
and second order spectra would overlap the first (desired) order, thus the
grating efficiency would have to be very high in the first order to minimize
light in the adjacent orders. When the grating arrived in late 1963, it was
found to have nearly equal intensity in the zero, first, and second orders,
and hence was unusable.
The study was not pursued further since it had been determined that
simple solutions were not possible and any other solution would require
more expense and Processor down time than was justified.
7. 7 Field Curvature
The most serious optical problem in the Processor is the fact that the
best focuses for the azimuth images lie on a curved surface. This curvature
causes the azimuth image to be out of focus by as much as one inch at some
ranges, depending on the initial adjustments. This causes a loss in resolu-
tion. The sources of this problem lie in the relay and cylinder lenses and
create a variation in magnification as well as focus. The simultaneous
The use of this term is not accurate since field curvature usually refers to
a non-astigmatic image. However, there are no better short names for the
effect and this terminology has been in use so it will be used here.
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correction of azimuth focus curvature and magnification variation without al-
tering the range image (which has a flat field) has proven very complex and
impractical to implement on the Processor. This problem has been the ob-
ject of much study and will be described in some detail here.
7. 7. 1 History of the Problem
Unlike most other difficulties encountered, the existence of a field cur-
vature problem was not suspected until late in the program. The lens system
designed was originally pursued until the system was of better quality than re-
quired, and the field was predicted to be flat. The computer programs could
not handle skew cylinder lens traces, but the apertures were small (f/30),
and the field angle was small (50) so off axis effects were expected to be
small. Experimental tests early in 1962 verified that the range image was
in focus on a flat field with or without the cylinder lens. Thus there was no
concern about the image plane flatness of the Processor. On the other hand,
there were many effects on both F101 data and simulated data which would
give curved fields for best azimuth focus. All out of focus problems en-
countered were ascribed (usually correctly) to one or more of these causes.
In the Spring of 1963 some new precision targets failed to give the ex-
pected quantitative results across the field, so a simpler target was made
and tested. In August, these tests uncovered the curvature of the surface
of best azimuth focus.
An analysis of the off-axis effects of cylinder lenses was made to deter-
mine the source of the curvature. Approximate first order theory and pre-
cision ray traces both verified the existence of the effect. Work began im-
mediately to find a method to eliminate the problem. A new set of interference
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filters were ordered* and calculations to determine the desired non-linearity
were begun. These calculations showed that the technique was not feasible
and emphasized the problem of obtaining uniform magnification as well as a
flat field. The theory presented in Appendix X was developed, and some
quantitative experiments on tilted cylinder lenses were performed.
In January 1964 accurate data was obtained that indicated that the field
curvature due to the cylinder lenses should be only one third as great as had
been found in.the Processor. The experimental Processor had become avail-
able and tests on it disclosed that the relay lens was the source of about two
thirds of the curvature. A new analysis of the relay lens uncovered an effect
of spherical aberration which usually is of little consequence but in the Pro-
cessor it leads to azimuth focus field curvature. This effect is described
below in Section 7.7. 3.
The further search for methods to correct the curvature soon lead to
the conclusion that there probably were no simple modifications which would
solve the problem. A rather extensive program would be required to formu-
late a solution, and the modifications would probably be costly. These anti-
cipated costs, combined with the uncertainty of anticipated improvements
and other project plans, indicated that further effort on the subject was not
justified at that time.
7. 7. 2 Measurement and Effect of Field Curvature
The most accurate data on the field curvature was obtained during the
The vendor required six weeks to procure and fabricate the glass before he
could coat the filters. They were eventually made linear as originally or-
dered. Although they duplicated previous filters, they were a better quality
and they provided the needed spares.
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This data was obtained primarily for
the purpose of optimizing the focus and drive ratio adjustments.
Figures 41 and 42 show the magnitude of the field curvature. The data
indicated by the solid line was obtained by using a test film covering the en-
tire range swath with identical targets. This test was run with a uniform
green interference filters instead of the wedge filter. The added focal shift
due to recorder CRT nonlinearity was computed and added to the above data
to obtain the curves labeled "net field curvature. " In the graphs the net
curve is asymmetric, in practice this theoretical situation is not evident
and optimum adjustments usually lead to a more symmetrical focus error.
The magnification variation is shown in Fig. 43. In practice the Processor
drive ratio is set to match the best average magnification. The image
broadening due to the magnification-drive ratio mismatch is approximately
.001" per percent error. Thus at the best compromise focus the image
spread would be less than . 001" over most of the range and would be about
002" at the extreme edges.
The effect of the curvature on the final map film is not straightforward
and not as serious as some of the calculations would indicate. It is clear
that the overall radar system cannot achieve the ultimate design goals with
the field curvature in the correlator. However, it has not been shown that
the present F101 tests would be significantly improved if the present Pro-
cessor were modified since there are sources of image degradation at the
edges of the field in the other components of the radar system. The present
adjustments in the system are optimized to give the best overall results,
and very little variation of azimuth image quality is noticeable over much
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Range Mark Range Mark
Range Mark Range Mark
Range Mark
5
Range Mark
6
If V V V V V
z
G)
1 2 6 7 8 9
~
~ir
Range Distance across film in inches
Figure 41
Azimuth Image Field Curvature (Near)
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Range Mark Range Mark
Range Mark Range Mark Range Mark
9
11
? T
_ V
5 6
-~. ~w Mo. : Mow Range Distance across film in inches
Figure 42
Azimuth Image Field Curvature (Far)
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1 2 3 4 5 6 7 8
Range Distance Across Film in Inches
Figure 43
Azimuth Magnification Across Field
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of the better correlated maps (for example in Fig. 4).
In cases where better azimuth focus for a particular target is desired,
the Processor can be refocused for that area. In addition, the best azimuth
focus is obtained on the detail correlator where field curvature is not a prob-
lem. Thus an improved Processor would add very little additional capability
to the overall development program at this time.
7. 7. 3 Sources of Field Curvature
The field curvature in the Processor comes from two known sources
acting independently, an off-axis cylinder lens effect and a relay lens spheri-
cal aberration effect. Both problems were studied in some detail, but both
are complex and the theory is not complete.
The curvature due to the cylinder lens can be considered to stem from
the fact that the radius of the lens surface is not constant for non-normal
cross sections. This results in a shorter focal length for rays traveling in
skew planes. In a large aperture optical system this would cause an axial
aberration, but in the Processor it creates a field curvature for the azimuth
images. The mechanism and first order analysis of the effect is given in
Appendix X. A more detailed analysis becomes very difficult since cylinder
lenses behave in a complex manner and there is very little literature on the
subject.
The curvature of the field contributed by the relay lens is a result of
spherical aberration of the relay lens as it is used for the azimuth image.
This lens is well corrected for the range image, but spherical and astigmatic
aberrations depend on the object position and are large for objects near the
''`There are 16 first order aberrations instead of the 5 in spherical systems.
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lens. Since the relay lens acts as a field lens, the spherical aberration does
not degrade the image, and the astigmatism is not an obvious problem since
we have only a one dimensional object (the azimuth image formed by the field
lens is the object in question). Field curvature is very nearly flat and should
be the same for all object points, and recent tests have shown that the field
curvature for the azimuth image is negligible. However, field curvature in
the relay lens is not the problem. Rather, the fact that images in different
portions of the output field are the result of slightly different paths through
the relay lens leads to the difficulty. Each of these paths has a slightly dif-
ferent optical power, and thus they form an image in a slightly different plane.
In most optical systems these images would be superimposed to form one re-
sultant image which would suffer from normal spherical aberration. However,
in the Processor these images are separated in range and thus each is still
of good quality but shifted along the axis. This gives rise to the peculiar
field curvature noted. This mechanism should have little or no effect on
magnification, a conclusion which is verified by experiment.
7. 7. 4 Field Curvature Corrective Techniques
A number of techniques to improve the azimuth focus have been studied.
The effect of shifting the image surface can be readily determined from first
order optical theory. The five techniques shown in Fig. 44 have been analized
with such theory. The effect of magnification, however, is not readily appa-
rent. In the Processor this is critical since a small variation in magnification
causes a relatively large image blur. This effect has been calculated for only
one of the techniques described below, in all other cases the magnification
will have to be considered as the overall system is designed.
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V
LV
(a) Field Flattener
LU V
V
W V
(b) Bent Cylinder Pair
V
~E_
(c) Non-linear Wavelength Filter
(d) Bent Imaging Cylinder
M
V
V
A
V
(e) Collimating Lenses
Figure 44
Field Curvature _~ rection Techniques
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The field curvature in a new design can undoubtedly be kept within the
depth of focus. The techniques described below will assist the designer in
his work, but the prime source of information will be the results of computer
runs which will trace skew rays and check for field curvature.
7. 7. 4. 1 Field Flattener
The common type of field flattener, shown in Fig. 44(a), cannot give
complete correction because it would cause the range image to de-focus as
rapidly as the azimuth image improved. In a new system the technique could
be used by designing a field curvature into the relay lens so as to match the
azimuth curvature, a rather cumbersome and difficult technique. In the Pro-
cessor it would be possible to improve the compromise: focus with a field
flattener, but it would be impractically thick (one to three inches) and the
effect on magnification would have to be checked.
7.7.4.2 Cylinder Lens Pair
A second field flattening device uses a pair of short focal length cylinder
lenses as shown in Fig. 44(b). In this technique the converging azimuth beam
is collimated and then reimaged onto a flat image surface. To achieve this
the negative lens must be located one focal length from the azimuth image
surface, and hence is bent to match its curvature. The azimuth image is re-
formed by adding a positive cylinder with the same numerical focal length.
The new image plane is located at the focal distance from this cylinder,
which would be straight. These cylinder lenses would have an inherent field
curvature themselves, but their design could compensate for that also. The
magnification problem is unclear, some simple considerations indicate no
variation but the validity of the assumptions is in question. These cylinders
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would be of a short focal length and be near the output image, so hopefully
would not degrade the image.
The theoretical questions left unanswered in the above paragraph were
to be checked experimentally if suitable cylinder lenses could be obtained.
It was felt to be impractical to manufacture the curved negative cylinder
with the correct bow in it, partly because of the need for an expensive accu-
rate design and partly because of the high cost of producing such a complex
lens. Therefore the possibility of obtaining plastic lenses that could be bent
to shape was investigated. Two possible vendors were contacted, a firm
in Boston which was working on new techniques to make high quality lenses,
and a leading plastic lens manufacturer. The techniques used do not give
precision optical quality, but sample lenses were fabricated by each firm,
both were of grossly inadequate quality and the investigation was dropped.
7. 7. 4. 3 Nonlinear Wavelength Filter
The position of the azimuth focus is influenced by the wavelength filter.
The technique of using a wavelength at each point which would cause the image
to lie in a flat plane was investigated. In this case the magnification could be
determined on a hand calculator. The calculation indicated that the magnifi-
cation causes a blur which increases about 10 times as rapidly as the out of
focus blur is decreased. For this reason this technique was abandoned.
7. 7. 4. 4 Bent Imaging Cylinder
The field curvature introduced by the cylinder lens could be eliminated
by causing the beam to pass through the cylinder lens perpendicular to its
This work was also being pursued for a similar problem in the recorder.
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cylinder axis. In theory this could be done by bending the cylinder lens as
shown in Fig. 44(d). In this case the lens is the main azimuth imaging lens
and hence must be of high quality although of modest curvature. This would
have to be manufactured with a torroidal surface, and it is unlikely that such
lenses are feasible.
7.7.4.5 Collimating Lenses
The field curvature introduced by the cylinder lens could be eliminated
by collimating the beam before it passes through any cylinder lenses as shown
in Fig. 44(e). These lenses would be large and would have to be of good opti-
cal quality. In concept they should be cylinder lenses, but spherical lenses
would probably be used. In a new system, this effect would probably be
achieved by the basic layout of the system rather than by the introduction of
special lenses.
7. 8 Noise and Stray Light
A major limiting factor in radar systems is noise in the output which
limits the weak signal resolution. In the system under discussion the Pro-
cessor acts to increase the "apparent" signal to noise ratio on the data film,
and it introduces additional noise onto the output map film. The first effect
has not been verified or studied in detail since it has been demonstrated in
the overall system and because the equipment and detailed knowledge of the
performance of the equipment has not been good enough to support a detailed
investigation in the Processor. The noise added by the Processor is intro-
duced by stray light, this latter subject has been studied in considerable
detail.
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7. 8. 1 Sources of Stray Light
Stray light was originally recognized as a serious problem. Many steps
were taken in the original design to minimize sources of stray light. Exper-
ience with the Processor in 1962 and 1963 indicated that the stray light level
was low, but not nearly low enough. Some efforts to keep the optics clean
and other simple steps were inadequate to reduce the stray light to a negli-
gible level. A more careful analysis of the sources of stray light was needed
and was done. The report of that work is included as Appendix IX.
The most surprising results of the study was the discovery that the en-
trance slit reflection is a serious source of stray light. The companion
problem of stopping and eliminating the main zero order image was obvious
and a carefully designed black mirror and light tray had been designed for
the zero stop*. The study disclosed that the entrance slit creates a similar
problem since all the light coming from certain parts of the slit structure
reaches the output film. Some steps have been taken to reduce this effect,
but the problem is more difficult since the entrance slit is a precision de-
vice and cannot be easily modified or redesigned. However, a suitable light
trap could be designed and built whenever the cost seems justified.
The stray light due to diffraction around the platen edges was found to
be strong but easily blocked. Two other sources, the multiple reflection
and mirror scattering, were found to be significant but. most solutions would
require major redesign and be impractical in the present Processor.
The most serious source of stray light is probably dust and scratches
on the collimator and platen glasses. Ideally there should be no such defects,
*See page 33 in Model 9015 Processor Final Report.
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but it is very expensive and difficult to eliminate them. The steps that could
be taken would be to refabricate some or all of the elements of the collima-
tor, field lens and first element of the relay lens. The possibility of
sacrificing some image quality for the advantage of fewer air-glass surfaces
in a simple achromat could be considered. A number of platen glasses
could be procured so that they could be replaced and resurfaced periodically.
The present dust covers are a compromise between accessibility to parts
and adjustments, ease of fabrication and installation, and dust prevention
effectiveness. This compromise could be reviewed and new covers made
if needed. Lastly, further steps could always be taken toward the ideal of
a clean room atmosphere.
7. 8. 2 Effects of Stray Light
The stray light will cause a base exposure on the output map film. Some
of this effect will be eliminated on the prints made from the film, but some
effects cannot be removed. The effects can be considered in three categories,
viz: uniform stray light, large scale variations (center to edge of film) and
small scale variations (streaks on the output film). The variation will only
be in range because of the film motion.
The uniform stray light will cause a base exposure or fog. The "DC
component" of this can be eliminated as described below, but the "AC com-
ponent" generated by film grain cannot be eliminated. Most of the noise
spectrum is below the resolution of the present map films and can be re-
moved by suitable printing devices if desired (it is usually just :ignored).
However, some of the noise is in the spatial frequency spectrum of the map
image, and this results in a loss in signal to noise ratio that cannot be
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recovered in subsequent printing or viewing procedures.
The proper printing exposure will normally compensate for a uniform
fog (the fog can be considered as an additional neutral density filter in the
printer). If the stray light has large scale variations, the compensation
should vary and hence dodging techniques would be necessary for complete
correction. The print will normally be high contrast (the output film has a
low contrast) and may need dodging to compensate for image exposure varia-
tion. The need to compensate for stray light thus requires more effort to
produce a high quality print.
The small scale variations will appear as streaks on the output film.
This will usually be caused by dust or other scattering sources near the in-
put platen which are imaged in the range direction. The seriousness of the
problem is best evaluated by examining the output map film or print.
7.9 Film Response
The system response and performance is a function of the characteris-
tics of each component in the system. The response of the films, especially
the data film, received a good deal of attention in the earlier phases of the
project. In photographic nomenclature, the response is usually included in
the slightly broader field of sensitometry.
The topic of film response was considered in the early design phases of
the project. There was serious concern that the data film could not have the
correct response and still cover the wide dynamic range anticipated. This
would require strong signal limiting in the electronics and possibly the dupli-
cation of the data film onto a print film before good correlatable data could
be obtained. The theory (or the application of the theory) was complex and
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the subject of best film sensitometry was left to be determined by experiment.
The first flight films were too poor to provide adequate data. for this in-
vestigation. The film (Kodak Aerial Tri-X) was processed normally, and
seemed to give as good results as could be expected. Early in 1.962 some
better flight films were duplicated at various contrasts and correlated. The
results of this test indicated that the contrast on the data film made relatively
little difference (other than reducing the dynamic range). This result was in
general agreement with day by day experience.
The reason for this lack of difference with film response seemed to be
partly that the coherent radar system is not as sensitive to this factor as
simple theory would indicate, and partly due to other over-riding sources
of image degradation - primarily phase errors due to aircraft motions and
nonlinearities introduced by signal limiting. The lack of accurate experi-
mental information indicated the need for a separate study. This was done
by an engineer who had worked in the coherent optics field for some time,
his report is included as Appendix XII. The findings indicate that the best
results would be obtained on the toe of the D-log E curve, and that the
sensitometry used is not optimum from the standpoint of eliminating ghost
images.
The general subject of system response was not intensively studied
during the period of mid 1963 to late 1964. It was assumed that. other prob-
lems would have to be solved before sensitometry would be an important
factor. During this period the film type, exposure and developing charac-
teristics have been set primrily on the basis of dynamic range, repeatability,
and previous experience. Continued experience with the system has brought
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about increased understanding of the problem, and it is now recognized that
the function which should be linear is the square root of coherent transmis-
sion as a function of input voltage to the recorder.
No films can meet this requirement exactly, but all films come close
over a limited range. It is likely that this subject will soon require more
attention, especially if some tests on radar response currently in progress
give the anticipated results.
In 1965 a study was made of film selection and chemical processing.
This indicated that some new films would give improved noise characteristics.
A report will be issued in July 1965.
7. 10 Cone Lenses
For monochromatic correlation of coherent side looking radar data the
optical system will have to have varying power in the range direction as is
described in Section 9. 0 and Appendix XIII. One conceptual solution to this
requirement is to use a cylinder lens with varying power along its length,
i. e. a cone lens. In the fall of 1963, Itek's optical shop made a cone lens
on an in-house research program to determine the feasibility of such a lens.
The program developed the necessary information to establish specifications,
feasibility and measurement techniques. It was concluded that such a lens
could be built if needed.
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PROGRAM SUPPORT
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8. 1 Introduction
Itek has assisted in the system test program by taking the responsibility
for processing the films produced by the airborne equipment. The prime
function has been to correlate the data films to produce map films.
Conceptually the developing and correlating of F101 flight test films
would be a routine service, but the intimate relationships between the Pro-
cessor, radar, and test conditions required an engineering effort to produce
the best test results and technical information. The fact that the Processor
was a new development and was undergoing subsystem testing and modifica-
tion indicated the need to keep it with the optical and photographic personnel
at Itek in Lexington until much of that work was finished. Table 7 shows the
schedule of the major Itek effort for the flight test phase of the program.
The flight tests are made by the Westinghouse Corporation from their
plant at the edge of Baltimore's Friendship Airport. The airborne equipment
is mounted in an F101 aircraft, and has been flown on over 100 data collec-
tion flights along the east coast, primarily over northern Virginia, Maryland,
and some of the coastal cities.
The radar is designed to mount in the final vehicle, and it was anticipated
that tests would be run with it in 1964. The move of the Processor to the west
in 1964 was made to provide close support for those tests. At the present time,
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Chemical processing
r Lexington
T West
I Baltimore
Z Duplicating
Lexington
r
Correlating
Full map, Lexington
Full map, West
Full map, Baltimore
Detail section, Lexington
1961
1962
1963
1964
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the emphasis is on work associated with the F101 tests, so the Processor
8.2 Procedure
The data film was exposed in the airborne recorder during the F101
flight. A flight number was assigned to the film (see Table 8) and it was
shipped to Itek via customer approved route. The film was chemically pro-
cessed, two duplicates were printed, and the data film was correlated. The
correlated film was developed and duplicated. One duplicate of each film
was returned to Westinghouse via the same route. The actual schedule of
events varied somewhat depending on the test and other work in progress,
but under normal procedures the flight was run in the afternoon, the data
film duplicate was shipped from Itek the next afternoon, and the map film
was shipped in the evening or on the following day. Technical information
concerning specific problems was usually conveyed by telephone in less than
24 hours after the flight.
The procedures were altered when the Processor was moved to the
western site and the various steps were performed at various locations.
At the present time all operations for the full map production are in Balti-
more, duplicates are sometimes sent to Lexington for further analysis on
the experimental Processor by Itek engineers.
The exchange and documenting of information was informal for the early
flights, but as the magnitude of the program grew a number of forms were
developed to help in the communication problem. The forms in current use
are included in Appendix XI. An additional sheet containing information
about the overall map quality and specific test results is also prepared and
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F101 Flight Film Code Numbers
First letter is S (assigned by Westinghouse)
Next number is flight number (assigned by Westinghouse)
Number in parenthesis is run number (assigned by Westinghouse)
(run number is not used if only one run is duplicated or correlated)
All films generated at Itek will have further information:
Duplicate
Correlated, near range
Correlated, far range
The next number indicates which duplicate or which correlation.
Additional D's indicate further duplications.
Hypothetical example:
S8
Flight test #8, original data film.
S8D8
Eighth duplicate of S8.
S8D8D8
Eighth duplicate of S8D8.
S8CN8
Eighth correlation. Used S8
near range.
S8D8CN9
Ninth correlation. Used S8D
8, near range.
S8(8)CF10
Tenth correlation. Used run
8 of S8 far range.
S8(8)CF1OD8
Eighth duplicate of S8(8)CF10.
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8. 3 Flight Test Results
This section will be a brief review of the results of the flight tests. This
topic has been of considerable interest to the Processor program because it
relates to the overall effort and also because it is one of the chief sources of
data for testing the Processor and correlation techniques. Unfortunately,
the F101 installation is very susceptible to wind directions and air turbulance,
a factor which reduces considerably the usefulness of the data obtained.
The first data film received was flight S5 flown on March 13, 1962. This
flight plus the two that followed provided very little weak data. Since it was
felt that this was due to a lack of power it was decided to fly at a lower alti-
tude. A change in the vehicle velocity compensated for the change of altitude
and made it practical to use the same parameters as the higher altitude. The
only variation was a change of slope in the hologram focal length vs. distance
curve which could be compensated for by using the five inch interference fil-
ters at the output. The low level flight had the advantage that more passes
could be made over one target area on the same flight.
The first flight which provided good data was Sll made on May 9, 1962.
This film was correlated sixteen times during the month and provided the
first opportunity to study the effects of adjusting various components of the
Processor. Such things as slit width, the amount of squint, rotation of the
slit and cylinders, mirror position, filters, focus of the various lenses,
drive speed were changed and exposures made both dynamically and statically.
The next few flights provided little data. In the meantime, the new cylin-
ders were received and installed in the Processor. S33 made in November
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provided the first fair low altitute map. This was also run under varying
conditions. S34 received January 3, 1963 had one good run and this also was
run many times. S37 was good also and run sixteen times during January
and February 1963 as was S40 during the next two months.
Since the power had been improved the next series of flights were at the
higher altitude. The first fair map was on S46 and the first good map was
S62 made in June 1963. This also was run many times. An attempt was
made to test the effects of photographic parameters (different product
gammas) on duplicates of S62, but the duplicating printer could riot maintain
the necessary tracking accuracy.
In October 1963 the airborne equipment was more reliable and during
the final three months of 1963 provided the best and more consistent data to
date (i.e. 12/31/64) By this time the Processor was operating well and a
good output map film could usually be made on the first: run.
A new set of airborne equipment installed in December 1963 gave gener-
ally poor results until May when S107 was run. This film resolved corner
reflectors separated by 10 feet. Many of the ensuing flight tests were de-
signed to study specific problems, and only a few are good overall map
films. 5119 gave a very good overall map (Fig. 30), while S123 resolved
corner reflectors separated by 5 feet (see Fig. 40).
8. 4 Field Support
The continuing technical problems on the program indicated that Itek
should continue to provide an engineering capability for flight test support
after the Processor was moved from Lexington. It was expected that the
flight test program would shift to the final vehicle, so arrangements were
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made to provide field service The move was ori-
ginally expected early in 1963, and during that year the Processor was
ready to ship on a month's notice. Additional personnel from Itek's Field
Support Group in Palo Alto, California were trained on the equipment, but
schedule changes prevented their use in the field
In 1963 the facility requirements
were drawn up. A
floor plan was made for placement of the Processor, fifteen-foot optical
bench, light table, sink, storage cabinets and work tables. This drawing
also included power and environmental requirements. A separate drawing
gave the location of the intake and exhaust ventilation for the Processor and
carbon arc. A room 191 feet square was allotted for the Processor and ad-
ditional space was provided in an adjacent office area. These rooms were
constructed in the Fall of 1963, during which time the Itek Field Engineer
made two trips to coordinate the work and become acquainted with the facili-
ties In general the facility was satisfactory except for a low
humidity problem and the dust brought in by the ventilation system. The
support services were very good.
The equipment was shipped from Lexington on March 18-20,
1964. A government aircraft was used, and the Field :Engineer accompanied
the equipment. Some of the ventilating systems had to be completed after
the Processor was on location, and the unit was checked out and processing
data films by the end of April.
Modifications to the Processor were designed so that they could have been
installed in the field if necessary.
The technician trained on the recorder program did provide field support.
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The two field personnel have processed data films, provided technical
liaison with the Westinghouse engineers, and run tests on the Processor
since that time. The most accurate data on field curvature and magnifica-
tion variation was obtained during the Summer.
Early in the Fall the possibility of relocating the Processor in Baltimore
was raised. Again plans were made, the equipment was crated, and was
moved across the country. The unpacking and check out of the Processor
took only a few days, and a number of flight films were run in December.
8. 5 Note Added in 1965
During the first five months of 1965 the two field personnel and the Pro-
cessor have been working at the Westinghouse plant in Baltimore. About 30
more flight films have been processed, and much attention has been devoted
to improving the general appearance of the films. The Westinghouse and
Itek engineers reinvestigated possible improvements to the Processor, but
most were found impractical on the same grounds as have been discussed
earlier in this report.
8. 6 System Support
The Itek Corporation has a system support responsibility in addition to
the basic Processor program. This system effort is a. part of the main 9015
project and is on an "as required" basis. Personnel on the recorder project
(Itek 9134) also contributed to the system effort.
Itek system support amounts to contributing optical capability to the
overall system design and evaluation done by personnel from Itek, Westing-
house, the government. Topics such as frequency bandwidths,
motion compensation, resolution budgets, and critical hardware problems
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In addition there has been continued contact by telephone and individual
visits. Many questions pertaining to the overall system have been investi-
gated experimentally or theoretically. Most of the work was of an informal
nature and the results of tests reported directly to the engineers involved.
One example of this effort concerns a request by Westinghouse for Itek to
examine flight films S105 and S106 to determine the cause of poor resolution
at the edges of the correlated map films. It was found. that the input data
quality was poor and the trouble was traced to a burned out tube in the focus
modulation circuit in the recorder. This was corrected and the next flight,
S107, gave good results across the whole field.
A third general area of system work has been in the planning of further
work and writing of proposals, most of which were written by individual
project teams but contained ideas contributed by all groups. The Westing-
house and Itek personnel also cooperated on a number of proposals and one
study for other coherent radar systems. These efforts were very fruitful
in stimulating new ideas and concepts which related to this project.
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NEW SYSTEM
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New knowledge and new devices have opened the way to improved pro-
cessors. These advances are being pursued by other organizations in the
coherent radar field and Itek has interpreted these advances in terms of the
present system. A summary of the new possibilities is given in this section
and in Appendicies XIII and XIV which are the correlator sections from a
recent proposal submitted to Westinghouse.
The most dramatic change has been brought about by the development
of the laser. This light source is ideally suited to the correlation process
and allows major advances in many aspects of the equipment. The bench
correlator has been able to take advantage of the laser to achieve high reso-
lution and high light levels. A new detail correlator recently proposed
makes use of the laser, see Section V(2) of Appendix X]:II.
The experience with the bench correlator has indicated the advantages
of visual observation of the correlated image. The light level is now high
enough for comfortable viewing at adequate magnification for a correlator
viewer. This type of device, termed a detail correlatorr, has the inherent
advantage that the operator can vary the correlator adjustments and observe
the results, thus he can extract more information from the data film than is
''`Two detail correlators were built during the first five months of 1965. One
was a simplified version of the bench correlator, the other was a console
unit.
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possible when only one map film is made with routine adjustments. The
simple detail correlator has no range compensation, a limitation that is not
serious in this unit. For small area photographic records, a small amount
of range compensation could be included rather easily if desired.
The detail correlator described in Appendix XIII is designed to be built
for minimum cost. It does not have many features and conveniences that are
usually built into. Photointerpretation film viewers. It is anticipated that high
quality viewers incorporating automatic film drives, mensuration equipment,
range compensation, large screens, etc. will be of great value in an opera-
tional system, but the proposed unit is considered to be adequate to lead the
way for such sophisticated viewers.
The laser is also the ideal source for a full film width Processor. A
new Processor us--ng a laser light source will produce! output map film at a
much faster rate, the time to process a full run will be cut from hours to
minutes. In addition, the laser eliminates the resolution loss due to a finite
wavelength band and thus will give better azimuth resolution.
The experience gained on the 9015 program has indicated that there are
a number of problems which are inadequately solved in the present Processor
It is felt that all the problems can be solved on the next unit if (a) suitable
development work is done on a few specific items, (b) the unit has adequate
flexibility for making minor modifications, and (c) no attempt is made to
make the unit compact of lightweight at this time. The unit described in
Appendix XIII is felt to meet these requirements. The flexibility required
for (b) also allows for the unit to be started before complete results are ob-
tained on the breadboard units for part (a).
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A number of reports and documents have been written on the project.
These are listed in Appendix I and a few are described briefly below.
10. 1 Final Report, Model 9015 Processor
This was published in May 1964. It describes the Processor and
sketches the basic theory of the unit. Since the Processor constitutes over
half of the entire program, that report is considered to be a separate section
of this final report. It is referenced and updated in Section 2. 0 of this report.
10.2 Final Report, Test and Simulation Program
This report was first published in April 1963. Much of the data was
soon out of date and so the report has been re-written and incorporated into
this report, primarily in Sections 5. 0 and 6. 0.
10. 3 Operational Manual
An operational manual was written in February 1963. It was published
in two sections, an unclassified portion describing the mechanical and elec-
trical devices and procedures, and a classified addendum which contains
optical adjustment information. Subsequent modifications have not changed
the operation very much, information relating to those changes are kept
with the log books. The first portion of the manual contains information
which may be of interest to people other than operators and is therefore
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included as an appendix to this report (Appendix IV).
10. 4 Monthly Reports
A short progress report has been submitted monthly. For a period of
about one year the report also contained some technical results from the
Test and Simulation program.
10.5 Drawings
A set of drawings has been maintained on the Processor. Time limita-
tions required some shortcuts (e. g. using layouts for assembly) during the
Summer of 1961, but the deficiencies have been corrected and the drawing
file has been maintained up to date with all the modifications.
A set of reproducible drawings were made for delivery in 1961, but it
was requested that instead of their being sent, the drawing file should be
continually updated so that the reproducible set could be remade and deli-
vered later. A new set has now been made and delivered.
10.6 Spares
The spare parts program was completed and parts delivered with the
Processor.
The list of recommended spare parts is included as Appendix V.
10.7 Acceptance Tests
A preliminary acceptance test was run in November 1961. A final accep-
tance test of the Processor and all associated equipment (i. e. the optical
bench units) was held in December 1963. No new equipment (other than
additions to the optical benches) has been built since that time.
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SUMMARY, CONCLUSIONS AND RECOMMENDATIONS
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11.0 SUMMARY, CONCLUSIONS AND RECOMMENDATIONS
11.1 Summary
For the past 4i years Itek has worked in conjunction with
the Westinghouse Corporation on a High Resolution
Coherent Radar system. Itek has contributed in a number of areas including
system support, field support, and the development of the film handling
equipment. One of these equipments, the recorder, was built on a subcon-
tract to Westinghouse and is discussed elsewhere (Project 9134 reports).
The other unit which was designed, built, improved and operated is a ground
based Data Processor. This Processor and the work associated with it
(Itek Project 9015) is the subject of this report.
The Processor was originally built on an accelerated schedule in 1961.
It incorporated some new techniques and had to achieve very high performance
in some respects. The unit performed very well in most respects, but did
not work as well in some other respects. The Processor design was based
on the use of a white light source and a "rainbow filter" using the then best
available components. Since that time the invention and production of lasers
has made the monochromatic design the best. During 1962 and 1963 the unit
was improved as some defects were corrected and as our knowledge of the
correlation process and astigmatic optics improved. The Processor was
used constantly during this time to support the F101 test program and to
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perform various tests and investigations on the correlation process.
During the last two years much of the effort was devoted to certain
basic problems of correlation, astigmatic optical systems, and coherent
radar data utilization. A bench correlator and test equipment was built and
studies were made. Some improvements were made to the Processor, but
most modifications were found to be impractical on the present unit. These
studies are discussed in this report (primarily in Section 7. 0) and the poten-
tial improvements are incorporated in a proposed new design covered in
Section 9. 0 and Appendix XIII.
The Processor is a functioning unit even though it has some problems
and limitations. It has produced many hundreds of feet of high resolution
radar data, much of which is reported to be as good as or better than any
other radar data produced by advanced systems.
11.2 Recommendations
11.2.1 9015 Processor
At the present time it is recommended that the present Processor,
bench correlator, and accessory equipment continue to be used as required
to support the F101 test program. This equipment is considered to be ade-
qute for test purposes, although it is inadequate to produce a good looking
full quality output map film.
11.2.2 Improved Processor
Whenever the capability to produce a full quality output film becomes
needed, it is recommended that a new correlator be built. Such a device
has been proposed, its chief features are outlined in Appendix :III.
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11.2.3 Further Studies
The overall field of coherent optical data processing is rapidly expanding
and a great deal of work is yet to be done. Continuing; studies on almost any
aspect of the problem would be worthwhile if adequately funded and staffed.
However, for the present situation it seems that the recommendations should
be directly related to the development of a new correlator to replace the 9015
Processor when and if it is needed. Most of the preliminary studies for such
a unit have been done, and the next step would involve rather comprehensive
programs in one of the two major problem areas, namely film drives and
astigmatic optical systems. Either or both of these efforts would be directed
directly toward the specific design outlined in Appendix XIII, and should cul-
minate in a prototype of the drive and servo mechanism and/or a working
optical system. Each of these programs would amount: to about one third of
the complete program to construct the Processor described in Appendix XIII.
Two other areas need improvement if full use is to be made of high
resolution coherent radar, a better recorder and better interpretation
techniques. It is believed that both areas are being investigated elsewhere,
but each should receive specific attention on this system if it is pursued
further.
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