SCIENTIFIC ABSTRACT OKHOTSIMSKIY, D.Y. - OKHREMENKO, N.M.

0 S 208/62/002/001/008/016 /1 On the behavior of shock vmves at ... D299/D303 thereby the computntioris were cttrried tbr-n1!t,'h to a pre!isure gradi- ent equal to 1,0018. The coinpiitationp vere further continued by meanz of S.A. Khristianovich's apizriximate method (Ref. 2: Udarnayn vo1na na znachitellnom rasztoyanii ot nests, vzry-va, Prikl. matem.i. mekhan.y 1956) 20) no. 5y 599-605). In additionj results are given relating to the formation ol the second shock wave in the negative- phase region. Denoti-ng by p) u, p, I) and e-, the presBure~ particle -velocity, density, shock velocity and coordinate of the shock front, one obtains (after transformations), thesystem +hziu+g-fP+d=0. (2.17Y aT 07) all fp + (2.18). OP a7 OZ (2.19) + 6~jj'+ C + h 0, b=. V-7)D C_ P V __ , e= 1. + t' (2.20) I 27j. jD -PU PD card 2/6 _F T.-  812061621002100110081016 On thi behavior of shock waves at ... 3)299/D303 The problem amounts to the integration of system (2.17)-(2.19) un- der the following boundary conditions: At the shock front e, 2 U= D - D7 7+1 (2-21) P 7 4:1+ IT 7-1 P 2 and at the left boundary u = 0. (2.22) System (2.17)-(2.19) was integrated by means of a second-order di'- ference scheme. The partial eerivatives were written in the form a/ ~ P, ++,, + n-, I - P, +, - n 2 JT"+3 (3.2) T)J+j - 711 < Replacing in Eqs. (2.17)-(2.19) the partial derivatives by finito Card 3/6  S/208/62/002/001/008/016 On the behavior of ffliock wives at D299/D303 differznceD, one obtains + ~ngn) 1/4 A. +V3 1+1 14,11, (3-3) CX-nP",~n+1 + + me 4~'Y- (u-+1 - B. J4-VS S+j W4 , 6+3 (3.4) aj"++"""' + M qVIVIJ Iij-in++,] + 1) R'++', + X (3-5) Tile system of difference equations (3.3)-(3-5) was solved by the .iell-Bhaft" m-ethod (developed by I.M. Gellfand and G.V. Lokutsi- yevskiy), Thereupon, S#A. Khristiwiovich's approximate method is used, involving the integral of the equations of motion of a sphe- riezil shock-wave, viz. 7-- 6= I] in -1 + -L6- (4.1) 'where (4.2) Ilith low pressures, one can pass fron the nuncrical coLlcul.,Alon (by the '"well-shaft" nethod) of the ~wive form to calculation by formu- la (4.1 ). The diotribution of the excess uressure rutj ciilculated by Card 4/6  'j ~J.:'/ U On the behaviox of shock waved a--. D 21 9 9/ D.-- 0 the appiox-Imate formula Z-% 17, - vi 14 Fur-ther~ the results of calculatiOM-_5 OrE given in fi~gureq an't t".. ble-9, The value oil m In formula (3~2) was iiie~- m 1- 112, The time-!3tep was 11~ -c - 0-:21,17988 t%0,730-~ se-- The nu-merl-a. tion was carried out 'to -rhe ra~)ment T could not. be carried out beycn6 hat ae the smoo-.hness ~f -th~e tion vas -Inpaized. The s&:c,,;laIVjon5 by he approximate me"lind ~v'.,e star,ted a litt"-7e earlier (a--. r - 58~,4;5'i ~,- The r e s i I T T 65-2342 c;cim:-ided for botLh th;- mmerical and approxm-, The approximate method was used for cal-,--,13-t-ing the ve-~ --ity r,-,,3- j/, trib-aticn -a, the rad2u~~ of the shock front and the -!e- locity i=ediately behind thp front. F '-om a figure, tbe tcna-~.,~-y profile reversal and sh,,)-I-.k-vmve -,n th;: neZ-L"I,E, '11,'na3c' r--- gion, is evident~ The tables sh.-1w the nosit.~-:)n -.z 'ni. fr3r~. the values of the uarameters i=ediately behir-id the shocck fr,'!nt ne a function of time, the distribution of -~he ex~es,, prossure, cle velo0ity and densiiy, the magmiudeL7 of the meas of -L.ive and negattlive ph--ses are also listed -,n a table; Th,3-r- m- Card 5/6  On he S li B 111 TT 2 D0,- A Vi; Card 6/6  O)WOMDEXTY., 1). Ye., and DUBCSM., 0, N.~ "Some problems of natrodynamice and celestial meebanies" report to be submittea for the 14tb Congress Intl. Astronautien 7ederation, Paris, FTance, 25 SeP-1 Oct 1963  icciSSIO-N, N" *R-,.-, A-T-3-006 8__3_4_____ AUTHORS: Okhotsimsi~4y,_D,Ye.; Sar hev, V.A. YC /61/0001016/000510009: TITLE: Gravitational stabilization system for artificial satellites SOURCE: AN SSSR.'Iskuset. sputniki Zemll, no. 16, 1963, 5-9 1 TOPIC TAGS: satellite, earth satellite, artificial eatellite, stabilization, stabilizer, satellite stabilization, satellite stabilizer, gravitational stabilizor, ;aerodynamic stability, aerodynamic stabilizer ABSTRACT: This theoretical paper examines the possible stabilization (STN) of a~ satellite (S) relative to a trihedron (TH) formed by the radius-vector, the tranfiver- sal, and the binormal to the orbit (0). This TH Is designated "the orbital coordi- nate system." The principle of STN Is based on the utilization of tha properties of the central Newtonian force field (CNFF) In order to orient a body moving therein .'in a specified manner. The body is assumed to have nonuniform moments of inertia relative to its-principal central axes. The existence offour .stable posItlons of relative equilibrium for a S moving in a CNFF Is stated. The scheme pi oposed ;includes the use of a dissipative element which consists of a central spherical cavity filled with a viscous liquid within the gravitationally stable S. The cavlt y ~_Card 1/3  AC-CESSION NR: AT3006834 ~'May also consist of a cavity lying between a spherical cavity -and a smaller spherl- Ical body. For a given thickness of a layer and a given density of the viscous fluid, !there exists an optimal viscosity which'affords the greatest damping rate for the ~oscillatory energy. A description Is given of the stabilizer (ST) proposed by the author in 1956 consisting of a spherical hinge attached to a satellite, with ~-!,equally long rods-carxying equal weights at their ends extending therefxom, Such _i .!a scheme is affective at elevations at which the aerodynamic drag is negligible. 'However, at 0 elevations below 600 ]an, the atmospheric effect must be talten into :account through consideration of the drag forces applied to the center of pressure :of the S and the ST bodies, directed In a sense opposite to that of the motion of the' iS. The gravitationally stable S-ST system -will be also a e rodynamic ally stable with ~a constant equilibrium position of the S and the ST relative to the orbital systern of ;coordinates, if the following conditions are satisfied: (1) If the axes connecting the' :center of mass of the S and the hinge point.of the ST and that connecting the hinge ~point of the ST and the midpoint of the two ST weights are axes of geometric Bym- metry of the S and the ST, respectively; (Z) both the S and th-s ST are not aerody- namically unstable; (3) the aerodynamic braking (ratio of the drag forces to the mass) of the&ST I a not greater than the aerodynamic braking of the S, that Is, them i acts as a kind of pa- -tational sta- rachute relative to the ST. The system of gravi "bilization proposed here can operate for a long time and does not require any C-2rd. 2/3  1,ACCESSION NR: AT3006834 ~expenditure of energyfor stabilization. The accuracy of the 13tabilizatlon olit S IBI! .'determined only by the manufacturing accuracy of the S-ST co-r-nbinatlonand can be' :extremely elevated. The weight of a ST required to achievo an optimal transient .,process, assuming rods having a length equal to twice the maximum linear Lmen-~ sion of the S, does not exceed a few percent of the S weight. (:)rlg. art. haB 2 figso- none SUBMITTED: 02jul6Z DATE ACQ: 08Aug63 EN C L-. 00 ;SUB CODE: AS, AP NO REP SOV: 001 OTHER: 001 i-Card. A-&.-  L - 18275--6a- ERA(b)/EWT ) FOC(w)/ .FS(v)-2/BDS/EED-2/,Ef1(v) _AFFIC/ AF1VQ F_S5-%kPGCASSD Pd-4/Pe-4 P -4 ACCE;~ 011 ACC Olt S72~9/63/00o/016/009 4/0123 ALTMOR Okbotaimagyx D, Ye,,; TITLE i Use of an earth-oriented satellite for'nolar investign~i"n xv SOURCE,. AN SSSR. lslmss4v*. swtni%i Zemai., no. .16, 19163 94-1 23 TOPIC TAGS: satellite attitude, orbital eleme'n't., solar -investigation, instra- rient illumination, satellite instnunentation ABSMACT: An analysis is made of soloz-41lumination of :Lnj3tr=cnts =.,ant,!d -on a satellite vith triaxial ctabjjkLq~jgp\Lona axis oriented to the earth, the second along the normal to the orbital plcLnc,, and the third along the tm,3- versal. A slight change occurs in the atttitude of the orbit relati" -to the sun oving to the yearly =tion off the ear"th around the sun and the regression of the orbital node of the satellite due to the oblatences of -the earth. The problem of determining the total ti= of ill=ination is solved 1) by dcte=.'_n- ing the illwmination time at a constant anple v bAmmen the direction to the sun and the normal to the orbital plane., tnd 2) by considering chanl--B in angle V vith time. Illumnination tiTn-- is the t:L-r-- the zwn 2--mains vithin the Card  L 18275-63 ACCESSTON M AT3006840 angle of viev of the instrument, To solve the first part, tbi naxim&l tl-n-- of instrument illumination during one orbit of the satellite at givenvnluis of angle v and instru:ment a-vigle of view.0 and with a Varying angle "bet,---cn -the optical axis of the instrir--nt and the axis of the satellite is sousbt. It �3 found that the maxin=1 illumination time --l-creexes as angle V decreases. The determination of angle V as a function of time makes it possible to establish its dependence on the angle of orbital inclination to the equatorial-21ance =d on the initial conditions (hour and date) of natellite launching. For a ty2icy~' orbit. (inclination to equator i - 65*; period of rotation TO - 90 min) the total ti= of i-l-Iii-Ina-tion taring a satellite lifetimo. can reach abo'At 60 bx optimal conditions and only about 15 hr for an instruwnt vith an anglo,- of 1-iev of 5'. Increasing the an-gle of viev Increases the 111,xnination ti--. Th~ totna. time of depend.9 on the bour and date of 1,munching, the positi--p of the. op-tical nxis of the in3tru=nt relative to the aatellite,, and the inclina '- tion of t'Zc- orbit. to the equatorial plane. Opti=-Itation of tbi orbital elcm-ents and ;)ro,(-ra.=-,d control of the position of the axis of the instrument can ln-.reasc illio,,%ination tite 2-10 timan. The amalysis supports the feasibility of UsLn-g eai~ ;-or;,ente(.1 satell1tes for, solar lnvestiration3, Orig. art. has: 25 and 23 formulas, Card 2/1  131 =V oha-lco.  ~SW, D. YE. (Noscov) "Study of notion in a ccntral -figl-! under tho effect oil colist"Int acceleration" Report prese4ted at the 2nd A 11-Union Congress on Theoretical and Ap-II.-Al Mechanics, Moscow 29 Jan - 5 .'eb 64.  LIDOV, H.L.; OMOISRraKY, DJE. (Yoscaw) "On a'method of investigating cebits in a restricted three-body problem". report presented at the 2nd All-Union Con,,-ress on I'heoretical and Applie3 Nechanic's, Moscow, 29 Zan - 5 Feb 6h.  DUBOSM., G.N.1 OKHOTSTMSKY. D.Ye. (Moscow): "Some problems of astrodynamics." report presented at the 2nd All-Union Congress on Theoretical and Applied Mechanics, Moscow, 29 Jan - 5 Feb 64.  MAIVUSTOV, C;*r-::;GTz- - --------- "Periodic solutions in the problem of two dimermional oscillatioru; of a satellite in an elliptical orbit." report submitted for !5th Intl Pstronaut.1cal 'long, Warsaw, 7-12 Sep 64. Corm flor Syace Research UBSSM.  OKHOTSIMSKIY., D. le.; ZLATOIJM"OV, V. A.; V. A.; -IVRDIFVSKrY, A. F. ".PeriocLic solutions in the problem of tvo-dimenBional oscillations of a oatellite In an eliptical orbit." report submitted for lltb Intl Cong of Applied Ypchwilci3) Mmichj, W. Geminy, 30 Aug-5 -Sep 64.  LIDOV, I.; OYJiUTSIWKIY,D . 'Ye. "Research on the categor.; of tra,,ectorj in the reBtrictei 3)roblem of t?zee bodies." report submitted for 15th Intl Astronautical Cong, Warsaw) 7-12 Sep 64.  'TiPIM ;7w7:. i S/0293/64/002/M~'06 5 ACCESSION NRI A?4046?71 __ V, A, C hoy'._V AUTHORt jjkjkqp U t ALA-R. y9 A T raheya jj 0 TI TLE iOaCtlIZ-L-Iong avi earth &acellite in the plane of ar. elliptic orbit ti ~r dY j JCosmic-heskl~ya isslodovaniya, v. 2, no, 5, 1964, 657-hlb ?1C TAGS: rth r8teilILV oncillationt p pailodic oacillation stability ARSTRAM 0(1CL1J*L!0,n1 of an artificial earth satellite LR tt~i: of an elliptic orbit under the oction of gravitational force a-F analyzed. The stated problem is reduced to determinins stable periodic oscLllatiana deficiibed by Lhe equation dO I + 41n V_16 4- v Rill 6 CoA 0 m 28 list V Where a in tho eccentricity of tho a:bit, v is the tr"e  ACCESSION NRI Aplli,146 1, 18 th* angle ~atwean one of prinr LtAll axqs of the a] lipsal d Iwartis vf the satelli!.e and the radi-as vactor of the orbit, A C w h ti r e A . B . and 1: are the principal cunt rt,,1 mc ,k a of the 'ki t F~ f. ;i u a u d e rintisfy ineq%ialltie- inerti 101 14 3, 0 < e C C, I-. r- ~i ~7 o 1 A F . To r E he vs k I y [ Kti iim 4 'bli, 66-1-6661 concerning th.1- fifladovantya. V. i, Qo~ 5 , 1FAtL-jq1;*tj~s a j ai%d the be!iavior of the adri, 2-,r-partodtc iolutlon~~ (1) are V58d for su~'Paquent qualitative analysis of r o 1~o tf- rm i t, a t 11 on o odd 2v-reriodic solutions is redl C - n r 1m, v-01~7*r ~.T-r-a-blem- for equatioti ~1' Ri I r v 0'~--t ti T --d-e Y U8:P N~ Variations is written for qjuatlon (1),And the root$ of ita t*vtstic equation bro aualy e d The results of the analyzi~,, 1' -~tic nrb t4 with arbltrary ecceiatricity, t~ t- tk4t. for plnne a a range of a valmea it ulhict; atabia psrio4Lc autiou i:f a SMLC- Is patzible. 1! e 4 0 4(,5 , lhofi stable DOCIllatiour of thC C A I arg possible for till vpluku of ir. t!lu ~rltervel 0 < 0.465, th2 larg*st pormistlbla vs;6e of a decreave DoCtILAtioue or tte satelliLe will, trace out n dumb-hel! sl#tap, ~i:- ja*vt jaku or i 8t 4A S f. flatirea and 10 form-alas.  ACCESSION 'RR AP40AM77' -ASSOCIATION t noile SUBMITTEDI 10 11 0 SUB CODE 90,111 a0vt 009 OT li E P. 009 ATD PRESS  17FS 8,1027,3/94/002/ 606/09 7' AFFIRt AUTHOR: Okbotsismskiy, D~ Ye TITLE, Investigation oi motion in F, cent-) field under the influenze of Donstant aweleration SOURCE: rzamichef;k1ye inv;l,~6uvaniya_ v 2. T-). 6, 1564, 817-842 TOPIC TAGS- 9-pacecraf t mation. tangentO,l acceleration. circular oe)it. space- it velocity, &,-Yar';_~raft thrust, gptcecraft tra)pctory, _ffight, circtdav velocity, hypcrt_-~.~iic v(I1,o,,jtv. (,i0,ctmj0t evne ABSTRACT, Due to the v-1BsJ1A'1ittet3 of using tJnctro)ect engines ior space flwhj~~ noed has arism for an In-s*;t1gr-t4on of the motion of apacocraft with givall thrust, Electrojet engtnaa can impai t to a apac-_rraft "tremely small acceleratitma #m t- e several mm/sec2. The usb uf a sinall, thrtist for pro. pulsion is pas8R).e only id, i, lbo spscevrvdi iota a satellitn orbit b-y engioes with a large thrust. Fitrther by electrojet enginea leade to motion of the apacer-rdt ir. a spiral trajectory 71 iv presents a method for computing mc4l!3n in a central field under the irdlulwee )f -av~-- aca*leratian of a oonstant value The authivre eonsideT a raW of velocitles fror (i - to hyperW110. Mho equationo of mation are presented " radvaW to tibnewrion) e,gi, cafd 1/2  L 21822-