Virtual antenna array with distributed aperture

What is claimed is: 1. A radar sensor, comprising: a plurality of multiple input multiple output (MIMO) radar transceiver devices, each including a plurality of transmitters and a plurality of receivers disposed within a local oscillator domain; and control logic coupled to the plurality of MIMO radar transceiver devices and configured to synthesize a virtual antenna array with a distributed aperture using the plurality of MIMO radar transceiver devices, the virtual antenna array including a first set of virtual array elements defined by one or more pairs of transmitters and receivers from the same local oscillator domain and a second set of virtual array elements defined by one or more pairs of transmitters and receivers from different local oscillator domains; wherein each MIMO radar transceiver device comprises an antenna-on-package device including a transmit antenna for each transmitter and a receive antenna for each receiver in the respective MIMO radar transceiver device, wherein the MIMO radar transceiver devices have a same antenna layout for the transmit and receive antennas thereon and are disposed on a common circuit board, wherein the plurality of MIMO radar transceiver devices includes first, second, third and fourth MIMO radar transceiver devices respectively arranged in upper left, upper right, lower right and lower left positions of a two-by-two array, wherein the second and fourth MIMO radar transceiver devices are each mounted on the circuit board in a same rotational orientation relative to one another, and wherein the first and third MIMO radar transceiver devices are each mounted on the circuit board at about a 180 degree rotational orientation relative to the second and fourth MIMO radar transceiver devices. 2. The radar sensor of claim 1 , wherein the MIMO radar transceiver devices are arranged on the circuit board with lambda/2 spacing. 3. The radar sensor of claim 1 , wherein the MIMO radar transceiver devices are non-cascadable transceiver devices. 4. The radar sensor of claim 1 , wherein the control logic is configured to trigger frequency modulated continuous wave (FMCW) chirps one or more of the MIMO radar transceiver devices using a trigger input thereon. 5. The radar sensor of claim 1 , wherein the control logic is configured to apply a global phase correction for the one or more pairs of transmitters and receivers in the second set of virtual array elements. 6. The radar sensor of claim 5 , wherein the control logic is configured to apply the global phase correction for the one or more pairs of transmitters and receivers in the second set of virtual array elements after performing a Doppler transformation operation for the one or more pairs of transmitters and receivers in the second set of virtual array elements. 7. The radar sensor of claim 5 , wherein the control logic is configured to apply the global phase correction by: performing initial beamforming to generate a set of initial beamvectors; identifying one or more correlated points from one or more pairs of transmitters and receivers in at least one of the first and second sets of virtual array elements; generating a set of ideal beamvectors for at least one of the MIMO radar transceiver devices; and generating the global phase correction by comparing the set of ideal beamvectors to the set of initial beamvectors. 8. The radar sensor of claim 1 , wherein the control logic is configured to align range profiles for the one or more pairs of transmitters and receivers in the second set of virtual array elements. 9. The radar sensor of claim 8 , wherein the control logic is configured to align the range profiles for the one or more pairs of transmitters and receivers in the second set of virtual array elements after performing a range transformation operation for the for the one or more pairs of transmitters and receivers in the second set of virtual array elements, and to perform transmitter code demodulation for the one or more pairs of transmitters and receivers in the second set of virtual array elements after aligning the range profiles for the one or more pairs of transmitters and receivers in the second set of virtual array elements. 10. The radar sensor of claim 1 , further comprising a plurality of local oscillator domains, wherein each of the plurality of MIMO radar transceiver devices is disposed within a local oscillator domain among the plurality of local oscillator domains such that any MIMO radar transceiver devices disposed within the same local oscillator domain operate using a common local oscillator signal, and any MIMO-radar transceiver devices disposed within different local oscillator domains operate using separate local oscillator signals. 11. A method, comprising: receiving radar data from a plurality of multiple input multiple output (MIMO) radar transceiver devices, each including one or more transmitters and one or more receivers disposed within a local oscillator domain; and synthesizing a virtual antenna array with a distributed aperture using the radar data received from the plurality of MIMO radar transceiver devices, the virtual antenna array including a first set of virtual array elements defined by one or more pairs of transmitters and receivers from the same local oscillator domain and a second set of virtual array elements defined by one or more pairs of transmitters and receivers from different local oscillator domains, wherein synthesizing the virtual antenna array with the distributed aperture includes identifying one or more correlated points from one or more pairs of transmitters and receivers in at least one of the first and second sets of virtual array elements and applying a global phase correction for the one or more pairs of transmitters and receivers in the second set of virtual array elements using the one or more correlated points to compensate for temporal or spatial mismatches between the first and second sets of virtual array elements. 12. The method of claim 11 , wherein applying the global phase correction is performed after performing a Doppler transformation operation for the one or more pairs of transmitters and receivers in the second set of virtual array elements. 13. The method of claim 11 , wherein applying the global phase correction includes: performing initial beamforming to generate a set of initial beamvectors; performing a nearest neighbor spatial matching algorithm to identify the one or more correlated points; generating a set of ideal beamvectors for at least one of the MIMO radar transceiver devices; and generating the global phase correction by comparing the set of ideal beamvectors to the set of initial beamvectors. 14. The method of claim 11 , wherein synthesizing the virtual antenna array with the distributed aperture includes aligning range profiles for the one or more pairs of transmitters and receivers in the second set of virtual array elements. 15. The method of claim 14 , wherein aligning the range profiles for the one or more pairs of transmitters and receivers in the second set of virtual array elements is performed after performing a range transformation operation for the for the one or more pairs of transmitters and receivers in the second set of virtual array elements, and wherein synthesizing the virtual antenna array with the distributed aperture includes performing transmitter code demodulation for the one or more pairs of transmitters and receivers in the second set of virtual array elements after aligning the range profiles for the one or more pairs of transmitters and receivers in the second set of virtual array elements. 1