Title: Implementing Standard Microsatellites for Responsive Space
1Implementing Standard Microsatellites for
Responsive Space a presentation for the AIAA
Responsive Space Conference Redondo Beach,
CA April 2, 2003
Jeff Janicik, Director of Flight Systems
2Responsive Microsats
- Design Constraints
- Methods of Meeting Design Constraints
- CHIPSat Case Study
- Launch
- Applications
3What are Responsive Microsats?
- Small (10-100kg) satellites that provide
immediate benefits to the end user - Design Constraints
- Minimal Cost
- Minimal Weight
- Maximum Capability
- Aircraft-Like Operability
- More emphasis on operational utility in the
design of a system than RD - Negative Impacts of RD approach
- Reduced error margin
- Increased support requirements
- Increased DTE
- Increased operating costs
The Usual Suspects
But how do you meet these design constraints?
4Method 1 Modularity
Mission
- DEFINITION Decomposition of a system into
modules - Effective modularization minimizes
interdependencies and most cleanly decentralizes
the system
Bus System
Power Subsystem
C2 Software
Tiers of Modularity within a Microsat Design
5Method 2 Common Industry Interfaces and
Protocols
- Use of well-supported, widely-used interfaces and
protocols eliminate the need for custom code - TCP/IP, IEEE, 1394, Commercial RTOSs, etc.
- Promotes rapid responsiveness for the ground
communications element - Integrated with global network as opposed to
being a bent-pipe to the global network
6Method 3 Standardization
- Experiment/Payload receives standard users guide
from the microsat provider - Build it, and they will come!
- I.e., RSDO (but much room for improvement)
- Development risk and modifications become the
responsibility of the experiment - PC plug-n-play Industry Model
- Standard hardware module plus software driver
CHIPsat Sept 01
7Method 4 Autonomy
- Minimal crew (one person, part-time) Mission
Control with anywhere, anytime monitoring - Modular intelligent flight software agents that
actively monitor and react to situations - Survivable, yet reduced complexity by limiting
spacecraft modes - Survive
- Orient
- Execute
- Commission within a few passes
8Case Study CHIPSat
- First-ever NASA UNEX microsat
- 30W OAV to payload, 300 MIPS / 6W
- 3-axis zero momentum bias
- 100 TCP/IP end-to-end comm architecture combined
with modular bus architecture - Custom code development was minimal at all levels
(VxWorks, Linux, Windows NT) - Internet tools open up wide range of operational
capability - Distributed IT and mission ops
- On-board and Ground Autonomy
- 100 survivable -- NO time-critical operations
- Rigorous test program to prove new miniature (3U
PCI) COTS-based SpaceDev avionics
9Case Study CHIPSat (contd)
10Result
- Responsive Microsat
- COTS standard interface
- Low-cost, high-volume
- Single-string, miniature, but capable
- Blue-suit operations
- Fundamental change in how we design satellites
- Operational utility incorporated into payload
design process before its even conceptualized - Faster implementation of technology
- Reduced emphasis on reliability
- Need rapid, low-cost launch capability!
11Responsive Launch
- Chicken or egg syndrome
- Small Launch Vehicles of the Future
- SpaceDevs High-Performance Mass Fraction (HPMF)
Hybrid SLV - Pump-fed, high O/F and N2O density
- TNT equivalent of nearly zero
- SpaceXs Falcon
- DARPAs RASCAL
- Others
12Application Technology Testbed
- Developmental and/or Follow-on TE for
acquisition space systems - Standard microsat busses can provide the core for
low-cost technology testbeds and reduce big
ticket program risks
- Less reliability on modeling and simulation
because empirical data can be achieved in a
timely and affordable fashion (test like you fly) - Existing model NASAs sounding rocket program
provides suborbital technology testbed
13Application On-Orbit Maneuvering and Transfer
- 6 standard microsats with imaging payload from
one ESPA launch stored in LEO waiting for tasking
to survey area of interest - SpaceDevs Maneuvering and Transfer Vehicle
(MTV-3) is a standard microsat bus with hybrid
propulsion capability - Storable, non-toxic, and re-startable
- 800 m/s delta-V, bias
- Move into low-altitude position and return by
command
14Application Launch on Demand
- Standard microsat bus combined with ISR payload
launched into low orbit over theater with data to
warfighter within hours - Could be used for short-term coverage while
larger, dedicated ISR spacecraft are maneuvered
or placed in orbit for permanent coverage
In-Theater
15Application Educational Payloads
- Ideal place to institutionalize new set of
rules with standard, modular, and autonomous
microsats - Students can build, launch, and operate payloads
before graduating - Microsat can be provided as heath-kit so
students can learn satellite design through
assembly and test - Investigation of a capable
3-axis stable bus at a recurring
cost of 500K - Predefined payload interface
16Summary
- Constrained by cost, size, capability, and the
need for aircraft-like operability - Responsive microsat design characteristics
- Modularity
- Common Protocols and Interfaces
- Standardization
- Autonomy
- Extensive range of applications for a standard
microsat provided responsive launch exists - Technology Testbed
- On-orbit Maneuvering and Transfer
- Launch On-Demand
- Educational Payloads