Small spacecraft processing and bus architecture

What is claimed is: 1. A spacecraft computing system, comprising: a first processor configured to process data from a payload and a first spacecraft system; a second processor configured to process data from a second spacecraft system; an interface connected to the second processor configured to interface with a third spacecraft system, wherein the second processor is configured to monitor the first processor and to initiate a recovery of the first processor when the first processor experiences a fault, and wherein the first processor's processing capacity is greater the second processor's processing capacity, wherein the first processor implements each of an autonomous maneuver planning and execution function, star tracking, global position system function, and digital radio function; wherein the second processor implements one of orbit control, attitude control system, housekeeping, command decoding, and data packetization; wherein the first processor is configured to process data from at least one of a camera head, star tracker, GPS, navigator front end, or radio receiver and the at least one of a camera head, navigator front end, or radio receiver do not have a processor; wherein the second processor is configured to process data from one of a transceiver, propulsion system, sun sensor, inertial measurement unit, and magnetometer. 2. The spacecraft computing system of claim 1 , wherein the second processor implements a management function configured to monitor and manage an operation of the first processor, wherein monitoring the first processor and initiating the recovery of the first processor is performed by a management function implemented by the second processor; wherein the second processor is configured to control power supply electronics on the spacecraft. 3. The spacecraft computing system of claim 2 , wherein the power supply electronics do not have a processor. 4. The spacecraft computing system of claim 3 , wherein the second processor is configured to control reaction wheels on the spacecraft. 5. The spacecraft computing system of claim 4 , wherein the second processor is configured to control a propulsion system on the spacecraft. 6. The spacecraft computing system of claim 5 , wherein the second processor is configured to survive a single event effect (SEE) of up to 37 MeV/cm2. 7. The spacecraft computing system of claim 6 , wherein the second processor is configured to survive a total ionizing dose (TID) of at least 30 krad. 8. The spacecraft computing system of claim 7 , wherein the second processor and interface is configured to survive a total ionizing dose (TID) of at least 100 krad with shielding. 9. The spacecraft computing system of claim 8 , further comprising memory connected to the second processor, wherein the memory and the second processor are space grade components. 10. The spacecraft computing system of claim 1 , wherein the first processor configured to process data from a payload and a first spacecraft system is configured to process data from a plurality of spacecraft systems. 11. The spacecraft computing system of claim 1 , wherein the first processor is configured to process data from each of a camera head, star tracker, GPS, navigator front end, or radio receiver and each of the camera head, navigator front end, or radio receiver do not have a processor. 12. A spacecraft computing system, comprising: a first processor configured to process data from at least one payload and a first plurality of spacecraft systems; a second processor configured to process data from a second plurality of spacecraft systems; and an interface connected to the second processor configured to interface with a third spacecraft system, wherein the second processor is configured to monitor the first processor and to initiate a recovery of the first processor when the first processor experiences a fault, wherein the first processor's processing capacity is greater the second processor's processing capacity, wherein the first processor is configured to receive a first plurality of data signals from the at least one payload and the first plurality of spacecraft systems, wherein the first plurality of spacecraft systems comprises at least two of a camera head, a star tracker, a navigation front end, and radio receiver, wherein the first plurality of spacecraft systems do not include an embedded processor for each of the first plurality of spacecraft systems, wherein the second processor is configured to receive a second plurality of data signals from the second plurality of spacecraft systems, wherein the second plurality of spacecraft systems comprises at least two of a transceiver, propulsion system, sun sensor, inertial measurement unit, and magnetometer, wherein the first processor implements each of an autonomous maneuver planning and execution function, star tracking, global position system function, and digital radio function based on the received first plurality of data signals processed by the first processor, and wherein the second processor implements each of orbit control, attitude control system, housekeeping, command decoding, and data packetization based on the received second plurality of data signals processed by the second processor.