ISRO Launch Vehicles
Indian Space Research Organisation
Server sky's best first use is rural computing in the developing world, and India's rural half billion could connect with their cell phones, through antenna panels on cell towers, to a modest server sky array. 12 low-population arrays can provide overlapping broadband coverage to villages up to the northern mountain valleys. Assume 12 "open" and 12 "managed" arrays in the first launch.
India has the technology to manufacture and assemble all components of Server Sky, except for some of the hafnium-gate integrated circuits, which (in 2013) must be made by Intel. Intel offers this technology to outside manufacturers under contract.
Using small 5300 5 gram thinsat arrays, spot size would be larger, but adequate for gigabit communication per village and small town. Assuming 50% extra weight for extra delta V to m288 and for apogee insertion motors (reusable in the future as ballast), and 3 spare launch bundles for backup, the entire system could launch with one 1000kg-to-LEO booster, or with 25 40kg-to-LEO boosters.
Server sky thinsat arrays are both much lighter than big-iron comsats, they are 7 times closer to earth than GEO, and can focus on much smaller ground spots. While a GEO comsat can focus on regions, server sky can focus down to city blocks, and multiplex transmit beams, while ground antennas can rapidly sequence between arrays .
ISRO's Launchers
|
first launch |
LEO kg |
GTO kg |
GEO kg |
|
PSLV |
1993 |
1860 |
1200 |
|
high success rate |
GSLV |
2001 |
|
|
2200 |
|
GSLV III |
2013? |
10000 |
5000 |
|
All vehicles launch from the Satish Dhawan Launch Centre (formerly the Sriharikota High Altitude Range ) at 13°43′12″N in Andhra Pradesh, 80 km north of Chennai (on India's southeast east coast). All these vehicles are larger than needed; perhaps they can launch many more than 25 arrays, selling them to other operators. Keep in mind that the arrays around the earth and below the horizon from India (70% of the total!) can serve other parts of the globe until they return to India's sky.
Estimated capacity to m288
The ISRO website claims 1600 kg "satellites" to a sun synchronous 620 km orbit, and a 1050 kg satellite to GEO. Does this include the apogee kick motor in the weight of the satellite? The above numbers from wikipedia are larger, but appear to be gross weight including AKM. Assume an inclination of 98 degrees for the 620 km orbit, meaning the plane of the orbit is 8° west of north.
Oversimplifying the trajectory a lot, a transfer orbit from sea level at 13.7 degrees north (est 6377 km radius perigee) to 620 km average altitude (6271+620 = 6991 km radius apogee) has a semimajor axis of 6684km, and an eccentricity of 0.04593 . v0 is 7730.5 m/s, vp is 8085.6 m/s, and va is 7375.5 m/s. The earth rotates at 7.292e-5 radians per second, or 465 m/s at 13.7N . We need to be moving north (or south) at 8085.6*cos(8°) = 7929 m/s, and retrograde by 8085.6sin(8°) + 465 = 1590 m/s for a total launch delta V of 8087m/s .
The apogee circularization is to an orbit with v0 = vp = va = 7550.9 m/s . The delta V is 175 m/s . The total delta V from Satish Dhawan to 620km orbit is approximately 8260 m/s .
The delta V to GTO from Satish Dhawan is about 9960 m/s . The delta V to m288 transfer AND insertion is around 9780 m/s . The mass is inversely proportional to the exponential of the deltaV divided by VE, the effective exhaust velocity (very crudely, this is for a curve fit). A change from 8260 to 9960 m/s (1700 m/s) reduces payload weight by a fraction of 1.54 or so, thus VE = 1700/ln(1.54) = 3880m/s .
Interpolating to 9780 m/s suggests a mass advantage over GTO of exp( (9960-9780)/3880 ) or 5%. Using the 1200kg to GTO number above, we get 1250 kg to m288, and using 1050 kg to GTO we get 1100 kg to a circular M288 orbit.
PSLV notes
- two early failures, 25 successes
- Stage 1 solid, 2 hypergolic, 3 solid, 4 hypergolic
PSLV-CA Core Alone 1,100 kg to 622 km SSO
PSLV Six strap-ons 1,678 kg to 622 km SSO
PSLV-XL Extended strapons +200 kg
PSLV-HP in development Extended strapons +400 kg
PSLV-3S in development 3 stage 500 kg to LEO
- 1993 D_1 - IRS-1E
- 1994 D_2 + IRS-P2
- 1995 C_1 ~ IRS-1D (only partial success)
- 1995-2008 C_2 to C_10 + 9 successes
- 2008 C11 + (-XL) Chandrayaan-1
- 2008-2014 C12-C23 + 12 more successes
2013 C25 + Mars Orbiter Mission . PSLV launch video - video shows three ISRO leaders: Liquid Propulsion Systems Centre director S. Ramakrishnan (probably?), ISRO director K. Radhakrishnan and SDLC director MYS Prasad
ISRO notes
chairman Koppillil Radhakrishnan
space center director M.Y.S. Prasad 4 May 1953 Andhra Pradesh
- doctoral degree in satellite communications from Birla Institute of Technology and Science.
- Bachelor of Engineering in electronics and communication from Government College of Engineering, Kakinada, Andhra Pradesh
Technical and legal issues surrounding space debris—India's position in the UN
Common but Differentiated Responsibility: A Principle to Maintain Space Environment with Respect to Space Debris Prasad2008d
Space Debris Mitigation Guidelines of the UN COPUOS Committee on the Peaceful Uses of Outer Space
A Policy Framework for Satellite Communication in India 1997
- Sriharikota High Altitude Range SHAR