Programmable code generation for radar sensing systems

The invention claimed is: 1. A radar sensing system comprising: a plurality of transmitters configured to transmit radio signals; and a plurality of receivers configured to receive radio signals that include the transmitted radio signals transmitted by the transmitters and reflected from objects in an environment; a code generator configured to generate first and second spreading code chip sequences, wherein the code generator comprises a plurality of shift registers configured to produce the code chip sequences; wherein first and second transmitters of the plurality of transmitters are configured to generate radio signals defined by the first and second spreading code chip sequences, respectively; and wherein a first receiver of the plurality of receivers is configured to process received radio signals as defined by a plurality of spreading code chip sequences that comprises at least the first and second spreading code chip sequences. 2. The radar sensing system of claim 1 , wherein each transmitter is configured to receive their respective spreading code chip sequence, and wherein each receiver is configured to receive the plurality of spreading code chip sequences. 3. The radar sensing system of claim 1 , wherein both the plurality of transmitters and the plurality of receivers are configured to receive spreading code chip sequences from a same source. 4. The radar sensing system of claim 1 , wherein the spreading code chip sequences comprise at least one of Hadamard sequences, Golay sequences, Frank-Zadoff-Chu sequences, and APAS sequences. 5. The radar sensing system of claim 1 , wherein the code generator is configured to selectively deliver spreading code chip sequences to the transmitters and receivers. 6. The radar sensing system of claim 5 , wherein the code generator comprises a controller, a logic device, and a memory, wherein the plurality of shift registers are feedback shift registers. 7. The radar sensing system of claim 6 , wherein the controller is operable to configure the plurality of feedback shift registers with any set of feedback connections. 8. The radar sensing system of claim 6 , wherein the logic device is configured to alter the output of the feedback shift registers in order to alter properties of sequences produced by the feedback shift registers, and wherein altering output of the feedback shift registers includes balancing the DC properties of the sequences, such that a sum of code chip values of 1 and 0 is below a DC threshold value. 9. The radar sensing system of claim 6 , wherein the memory is configured to store spreading code chip sequences, and wherein the controller is operable to select a respective spreading code chip sequence from the stored spreading code chip sequences for each transmitter of the plurality of transmitters. 10. The radar sensing system of claim 6 , wherein the memory is configured to store the first spreading code chip sequence, and wherein the code chip generator is configured to output the first spreading code chip sequence for the first transmitter of the plurality of transmitters, and further configured to output delayed versions of the first spreading code chip sequence for each of the other transmitters of the plurality of transmitters. 11. A code generator configured for a radar sensing system, the code generator comprising: a plurality of feedback shift registers configured to generate a chip sequence; and a controller operable to configure the plurality of feedback shift registers with selected sets of feedback connections, wherein the selected sets of feedback connections cause the plurality of feedback shift registers to generate selected chip sequences; and wherein the selected chip sequences are output to a plurality of transmitters and to a plurality of receivers of the radar sensing system for generating and processing radio signals, respectively. 12. The code generator of claim 11 , wherein the selected chip sequences comprise at least one of Hadamard sequences, Golay sequences, Frank-Zadoff-Chu sequences, and APAS sequences. 13. The code generator of claim 11 further comprising a memory configured to store chip sequences, which include a respective chip sequence for each transmitter of the plurality of transmitters, wherein the controller is operable to select the respective chip sequence for each transmitter of the plurality of transmitters, and wherein the chip sequences are spreading code chip sequences. 14. The code generator of claim 11 further comprising a memory configured to store a first chip sequence, wherein the controller is operable to control the output of the first chip sequence to a first transmitter of the plurality of transmitters, and further operable to control the output of delayed versions of the first chip sequence for each of the other transmitters of the plurality of transmitters. 15. The code generator of claim 11 further comprising a logic device configured to alter the output of the feedback shift registers to alter properties of chip sequences produced by the feedback shift registers. 16. The code generator of claim 11 , wherein the controller is operable to control the logic device to balance the DC properties of the chip sequences, such that a sum of chip values of 1 and 0 is below a DC threshold value. 17. A method for generating chip sequences for a radar sensing system, the method comprising: generating, with a plurality of feedback shift registers, chip sequences; selecting a plurality of feedback connections for the plurality of feedback shift registers, such that the plurality of feedback shift registers generates selected chip sequences; and outputting the selected chip sequences to a plurality of transmitters and a plurality of receivers of the radar sensing system for generating and processing radio signals, respectively. 18. The method of claim 17 further comprising storing chip sequences into a memory, and selecting, from the memory, respective chip sequences for each transmitter of the plurality of transmitters. 19. The method of claim 17 further comprising altering the output of the feedback shift registers to balance DC properties of the chip sequences produced by the feedback shift registers, such that a sum of chip values of 1 and 0 is below a DC threshold value.