SUNBLAZER ORBITS John V. Harrington

SUNBLAZER ORBITS John V. Harrington

FIRST-ORDER ANALYSIS OF SUNBLAZER ORBITS John V. Harrington Reissued as CSR TR-66-10 October 1966 FIRST-ORDER ANALYSIS OF SUNBLAZER ORBITS by John V. Harrington A vehicle launched from the earth and accelerated to a velocity slightly greater than the terrestrial escape velocity will be injected into a heliocentric orbit, the orbital param- eters being determined by the vector relationship between the earth's orbital velocity and the excess velocity of the vehicle after it has achieved terrestrial escape. In the simplest situation and, for purposes of a solar probe the most useful situation, the excess velocity is caused to be exactly opposite to the earth's velocity. The vehicle will then be injected into an orbit with aphelion at 1 A.U. and perehelion less than this by an amount depending upon the magnitude of the excess velocity. The relationship between these is given by: where vcl is the circular orbital velocity for a 1 A.U. orbit and r is the perehelion distance measured in A.U. P To achieve the excess velocity Av, the launch vehicle must have attained a velocity vb at burnout of: 12 I vb = + Av2 where vegC is the escape velocity at the burnout altitude. The sidereal period of a satellite in such a heliocentric orbit -2- follows directly from Keppler’s third law. When the units of time are chosen to be years and distances are in A.U., the expression for the period has the relatively simple form: 3/2 131 T=(’ir.p 1 From these fundamental rehtionships the data in Tables I and 11 are computed as an indication of the orbits achievable when small payloads are boosted to velocities slightly in excess of escape velocity. It would seem at first glance that almost any of these orbits would be useful in the sense that they all will allow a transmission path to be set up between the satel- lite and the earth which eventually must penetrate the inner corona. Some further analysis, however, indicates that there is a preferred family of orbits leading to the most desirable experimental situation. Retrograde Injection If superior conjunction is made to occur on the line of apses of the satellite orbit, a symmetry in the transmission path geometry before and after conjunction occurs. Since the most important measurements to be made by the Sunblazer vehicle are the transmission path delay measurements as the path pene- trates the corona, the opportunity to repeat the measurements with the same path geometry after conjunction seems most attrac- tive. The transmission path length and offset have been cal- culated (Figures l, 2, 3) for satellites launched in a retro- . -3- u1 k R (c In W I- In W. m 0 Q\ 00 8 d 4 d 0 0 to & 3( ln 0 N w 0 PI (c l-l b\ 12 0 W 8 m N N rl l-l FI 3.( 0 o\ m 00 co rn 0 F IC W w \D . 0 . d 0 0 0 0 0 fi 0 m N W l-l N N m. m 0 0 0 0 0 0 G 2 0 l-l m In N t- 0 b v) m VI cr . 0 . d 0 0 0 0 0 u Q) UJ 3 W sr: I- w m fi b\ * 0 co N In I- Q\ rl l-l l-l l-l V 6) M \ 4J VI M r- (c v) W W In e . co (c m a rl m m m v * a -4- -. rl d 0 4 rQ do 0 m N uQ) -d d rl Q) 4 In a ui VI rl & a rl 0 to k 0 w In m FI. k 0 uQ) i! ki! nl pc d id 4 IC -4 v). rl 0 0 H H I3!i v 0 N rl In 0 00 m -5- grade direction, using three possible values for launch velo- cities. Direct inspection of the three sets of curves will show that the path symmetry is best achieved for Case 2 in which the launch velocity is of the order of 40,000 feet per second. It is instructive to examine further the conditions under which this symmetry is achieved to determine what other orbits may also be acceptable. If oo = 2n radian per year is the mean angular velocity 2n of the earth about the sun and os = - is the mean angular velocity of the satellite, then the relative angular velocity w r = (us - oo) multiplied by tn,the time to conjunction, must satisfy the relation: [41 (us - wo)tn = nn; n = 1, 3, 5, . where n is an odd integer and is a measure of the number of synodic half-periods between launch and conjunction. The con- dition that conjunction occur on the line of apses requires that the earth be on this line at that the so that: 1 (51 tm=m* z where m is any integer and is a measure of the number of half- earth rotations (half-years) between launch and conjunction. By eliminating tmin [4] and (51 and solving for ts, we find that the family of satellite periods which will satisfy the desired symmetry conditions is given simply by: = m r61 tS n + m yrs . -6- In Table I11 are listed the preferred satellite periods for the first few values of n and m. Periods below 0.353 years are not achievable since this corresponds to r = 0. P Of the first three of these possible orbits, the one for which n = 1, m = 2 appears the most attractive since the neces- sary launch velocity (39.4 K ft/sec) seems practically achievable and the time to conjunction (1.0 yr) is not too long (Table IV) . Direct Injection- When the satellite is launched so that its excess velocity adds to the earth's orbital velocity, it is injected into an orbit with perehelion at 1 A.U. and aphelion several times greater than this. The conditions for symmetry may be set down in much the same manner as before requiring (wo - us) tT= nr, but now the time to conjunction tv must equal k half periods of the slowest orbiter which is now the satellite. The result- ant expression for permissible satellite periods is then: (71 t*=7+ Y ears From the tabulation of preferred satellite periods in Table V, it is evident that the earliest conjunction time is obtained for n = k = 1, and this is also achievable by a reason- able launch velocity (Table VI). Effect of Injection Errors If we adopt as an objective the retrograde injection of the satellite into a heliocentric orbit having a perehelion at TABLE 111. Orbital Periods for Superior Conjunction on Line of Apses Earth Satellite Period Time to Half Periods Years Conjunction t* = m2 m- n=l -n=3 n=5 1 0.50 (0.25) (0.167) 0.5 yrs. 2 0.667 0.40 (0.286) 1.0 3 0.75 0.50 0.375 1.5 4 0.80 0.555 0.444 2.0 5 0.833 0.625 0.50 2.5 6 0.855 0.667 0.555 3.0 7 0.875 0.700 0.583 3.5 . ,. ,. -8- 0 a, m \ 4 W $3 4 rn rn aJ xu w c 0 0 4 UUL) b k alEL a, N fd rl ac 7 VI k 0 W * El4 r\l cr) d * E h -9- 0 m 0 0 . 0 m m w In m k h 0 In 0 0 . 0 0 N cv m w E h 0 In 0 0 0 . 0 . 4 l-4 cv m m k h l- 0 m Q 0 . 0 0 \o m F cv VI k h 0 0 m 0 a 0 0 . w N cv rl VI r( k $.( ll m 0 0 m m cv c . 0 cv rl rl rl aVI 0 -4 k al 2414 N m w In . pc - 10 - m c, a-4 k 0 n rl ti -k 0 -4 4 a3 N m c W -3. H I2 8 4 r( 4J 0 0) k -4a E: 0 I 0 -4 Iv1 -94J k s h molno 0. OFIFIN rn k h m olnm 8Nrid - 11 - 0.53 A.U., then the sensitivity of the desired orbit to orien- tation errors in the excess velocity vector may be studied. An elliptical orbit is characterized by the following equations where 8 is the argument of perehelion, B is the anqle between the injection velocity vector and the direction orthogonal to the radius vector; k = is the ratio of the injection velo- V C city to the circular velocity at that radius; e is the eccen- tricity of the orbit, and a is the semi-major axis. - k2 sin 8 cos 181 tan * - (k2-1) cos2g-1 -=a 1 r 2-ki Since the injection velocity v is obtained by adding the very small excess velocity BV to the relatively large earth's orbital velocity vc, it is evident that the angle 8 cannot be very large. In fact, its maximum value in the unlikely case that the excess velocity misses the preferred direction by 90° is only 0.15 radians or 9'. Thus tan e for all cases of interest to us is given by: k2 sin B tan 8 % k2 - 1 and . - 12 - r 131 e2 'L (k2 - 1)2+sin2 8 Consider the case where AV lies in the ecliptic but is displaced from its intended orientation by an angle a.

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