Multi-chip synchronization for digital radars

The invention claimed is: 1. A multi-chip MIMO radar system comprising a plurality of chips, the MIMO radar system comprising: a first integrated circuit chip (chip) of the plurality of chips comprising a first plurality of transmitters and a first plurality of receivers; and a second chip of the plurality of chips comprising a second plurality of transmitters and a second plurality of receivers; wherein the second chip is configured to align an own internal timing clock value of the second chip with respect to a reference clock signal, and wherein the first chip is configured to align an own internal timing clock value of the first chip with respect to the reference clock signal, wherein the reference clock signal is defined by the first chip, such that the internal timing clock value of the second chip is aligned to the internal timing clock value of the first chip, and the first pluralities of transmitters and receivers are respectively synchronized with the second pluralities of transmitters and receivers; and wherein the second chip is configured to delay the reference clock signal at the second chip by a selected multiple of a sub-value of the reference clock signal such that the delay of the reference clock signal at the second chip accounts for propagation delays of the reference clock signal. 2. The multi-chip MIMO radar system of claim 1 , wherein each chip of the plurality of chips is configured to perform an intra synchronization such that all transmitters and receivers of each chip are synchronized. 3. The multi-chip MIMO radar system of claim 2 , wherein each chip of the plurality of chips comprises a local clock operable to generate a common clock signal, wherein each chip is configured to divide a respective common clock signal such that each transmitter and receiver of each respective chip receives a respective sample clock signal derived from the respective common clock signal, and wherein each chip is configured to synchronize respective transmitter clock dividers and receiver clock dividers to transition on a same edge as their respective common clock signals. 4. The multi-chip MIMO radar system of claim 2 , wherein each chip is individually operable to delay clock signal values by selected multiples of a sub-clock value to account for different transmitter/receiver routing on the respective chips. 5. The multi-chip MIMO radar system of claim 1 , wherein the first chip is a MASTER chip and each of the other chips of the plurality of chips are SLAVE chips, such that the SLAVE chips synchronize their operations with respect to the MASTER chip. 6. The multi-chip MIMO radar system of claim 1 comprising a reference clock operable to transmit the reference clock signal that is received by the first and second chips, wherein the second chip is configured to synchronize with the first chip with respect to the reference clock signal received by the first and second chips. 7. The multi-chip MIMO radar system of claim 1 , wherein the first chip comprises a reference clock operable to transmit the reference clock signal that is received by the first and second chips, and wherein the second chip is configured to synchronize with the first chip with respect to the reference clock signal received by the first and second chips. 8. The multi-chip MIMO radar system of claim 1 , wherein a first portion of the plurality of chips are used for a first scan, and wherein a second portion of the plurality of chips are used for a second scan. 9. The multi-chip MIMO radar system of claim 1 , wherein a first portion of the plurality of chips performs a first portion of post processing of received data, and wherein a second portion of the plurality of chips performs a second portion of the post processing of the received data. 10. A method for synchronizing the chips of a multi-chip MIMO radar system, the method comprising: powering up each chip of a plurality of chips and starting local clocks of each chip; intra synchronizing transmitters and receivers of each chip of the plurality of chips; performing a first synchronization of the plurality of chips with respect to a reference clock signal received by each of the plurality of chips, wherein the reference clock signal is defined by a first chip of the plurality of chips, wherein the first synchronization comprises synchronizing respective own timers of the plurality of chips to the reference clock signal; and performing a second synchronization of the plurality of chips, wherein the second synchronization comprises: transmitting, with the first chip of the plurality of chips, a scan of a selected duration comprising a selected quantity of codes of a selected pattern; receiving, with the plurality of chips, the radio signal that is the transmitted scan; correlating, with the plurality of chips, the received radio signal; using the correlation output of a second chip of the plurality of chips to determine an offset between the second chip and the first chip; and adjusting a clock signal of the second chip such that the offset between the first chip and the second chip is reduced to below a threshold value; wherein adjusting a clock signal of the second chip comprises delaying the reference clock signal at the second chip by a selected multiple of a sub-value of the reference clock signal; and wherein the second synchronization of the plurality of chips synchronizes the transmitters and receivers of the second chip to the transmitters and receivers of the second first chip to account for a propagation delay of the reference clock signal. 11. The method of claim 10 , wherein each chip of the plurality of chips comprises a local clock signal that is divided such that each transmitter and receiver of each respective chip receives a respective sample clock that is derived from their respective common clock signals, and wherein intra synchronizing the transmitters and receivers of each chip comprises initiating a START signal on each chip that synchronizes all respective transmitter dividers and all receiver dividers to transition on a respective same edge of their respective clock signals, such that the transmitters and receivers of each respective chip are synchronized. 12. The method of claim 11 , wherein each chip individually delays each of their respective clock signal values by selected multiples of a sub-clock value to account for different transmitter/receiver routing on the respective chips. 13. The method of claim 10 , wherein the first chip is a MASTER chip and each of the other chips of the plurality of chips are SLAVE chips, such that the SLAVE chips synchronize their operations with respect to the MASTER chip. 14. The method of claim 13 , wherein performing the first synchronization of the plurality of chips comprises transmitting, with a reference clock of the first chip, the reference clock signal, wherein the reference clock signal is used to synchronize timers of each SLAVE chip to a timer of the MASTER chip. 15. The method of claim 13 , wherein performing the first synchronization of the plurality of chips comprising transmitting, with a reference clock of the radar system, the reference clock signal, wherein the reference clock signal is used to synchronize timers of each SLAVE chip to a timer of the MASTER chip. 16. The method of claim 10 , wherein the first synchronization of the plurality of chips synchronizes the plurality of chips to within 10-100 ns. 17. The method of claim 10 , wherein the duration of the transmitted scan is one pulse repetition interval. 18. The method of claim 10 , wher