Wide field of view volumetric scan automotive radar with end-fire antenna

What is claimed is: 1. A vehicular radar system for performing a volumetric scan of an environment of a vehicle comprising: a plurality of end-fire antennas including: a first array of end-fire antennas positioned along a first plane and having a transmission end oriented in a first direction, a second array of end-fire antennas positioned along the first plane and having a transmission end oriented in a second direction that is different than the first direction, a third array of end-fire antennas positioned along a second plane above or below the first plane and having a transmission end oriented in the first direction, and a fourth array of end-fire antennas positioned along the second plane and having a transmission end oriented in the second direction; and at least one radio frequency integrated circuit (RFIC) coupled to the plurality of end-fire antennas and configured to control the plurality of end-fire antennas to scan for objects in the first direction, the second direction, and between the first direction and the second direction by transmitting signals of varying phases to the plurality of end-fire antennas. 2. The vehicular radar system of claim 1 further comprising a first printed circuit board (PCB) and a second PCB and wherein the first array of end-fire antennas and the second array of end-fire antennas are positioned on the first PCB and the third array of end-fire antennas and the fourth array of end-fire antennas are positioned on the second PCB. 3. The vehicular radar system of claim 1 wherein the first array of end-fire antennas and the third array of end-fire antennas are configured to detect three-dimensional data in the first direction and the second array of end-fire antennas and the fourth array of end-fire antennas are configured to detect three-dimensional data in the second direction. 4. The vehicular radar system of claim 1 wherein: the plurality of end-fire antennas further includes: a fifth array of end-fire antennas positioned along the first plane and having a transmission end oriented in a third direction that is different than the first direction and the second direction, and a sixth array of end-fire antennas positioned along the second plane and having a transmission end oriented in the third direction; and the at least one RFIC is further configured to control the plurality of end-fire antennas to scan for objects in third direction and between the second direction and the third direction. 5. The vehicular radar system of claim 1 further comprising: electrical leads between the at least one RFIC and each of the plurality of end-fire antennas; and a radar mount having: at least two walls each oriented perpendicular to the first plane and the second plane and having at least one flange configured to support the plurality of end-fire antennas, a cover configured to be positioned above the at least one RFIC and defining a plurality of openings each configured to receive one of the electrical leads to reduce transmission of undesirable signals away from the vehicular radar system, and a radome configured to at least partially enclose the plurality of end-fire antennas and to reduce reflection or loss of the signals transmitted by the plurality of end-fire antennas. 6. The vehicular radar system of claim 5 further comprising a radar processor coupled to the at least one RFIC and configured to receive signals from at least some of the plurality of end-fire antennas via the at least one RFIC and to process the signals, wherein: the radar mount further includes a base defining a cavity; the radar processor is positioned in the cavity of the base; and the radar mount further includes an edgeboard positioned on one of the at least two walls and configured to transmit signals between the at least one RFIC and the radar processor. 7. The vehicular radar system of claim 1 further comprising a camera configured to detect image data corresponding to the environment in at least one of the first direction, the second direction, or between the first direction and the second direction. 8. The vehicular radar system of claim 7 further comprising an electronic control unit (ECU) coupled to the camera and the at least one RFIC and wherein: at least some of the plurality of end-fire antennas are configured to transmit a signal and at least some of the plurality of end-fire antennas are configured to receive a reflection of the signal; and the ECU is configured to determine characteristics of an object based on the reflection of the signal and to at least one of verify or supplement the characteristics of the object based on the detected image data. 9. A vehicle capable of three-dimensional scanning of an environment of the vehicle comprising: a plurality of end-fire antennas including: a first array of end-fire antennas positioned along a first plane and having a transmission end oriented in a first direction, a second array of end-fire antennas positioned along the first plane and having a transmission end oriented in a second direction that is different than the first direction, a third array of end-fire antennas positioned along a second plane above or below the first plane and having a transmission end oriented in the first direction, and a fourth array of end-fire antennas positioned along the second plane and having a transmission end oriented in the second direction; at least one radio frequency integrated circuit (RFIC) coupled to the plurality of end-fire antennas and configured to receive signals from the plurality of end-fire antennas and to control the plurality of end-fire antennas to scan for objects in the first direction, the second direction, and between the first direction and the second direction by transmitting signals of varying phases to the plurality of end-fire antennas; and an electronic control unit (ECU) coupled to the at least one RFIC and configured to determine characteristics of an object in the environment based on the signals received by the at least one RFIC. 10. The vehicle of claim 9 further comprising a first printed circuit board (PCB) and a second PCB and wherein the first array of end-fire antennas and the second array of end-fire antennas are positioned on the first PCB and the third array of end-fire antennas and the fourth array of end-fire antennas are positioned on the second PCB. 11. The vehicle of claim 9 wherein the first array of end-fire antennas and the third array of end-fire antennas are configured to detect three-dimensional data in the first direction and the second array of end-fire antennas and the fourth array of end-fire antennas are configured to detect three-dimensional data in the second direction. 12. The vehicle of claim 9 wherein: the plurality of end-fire antennas further includes: a fifth array of end-fire antennas positioned along the first plane and having a transmission end oriented in a third direction that is different than the first direction and the second direction, and a sixth array of end-fire antennas positioned along the second plane and having a transmission end oriented in the third direction; and the at least one RFIC is further configured to control the plurality of end-fire antennas to scan for objects in third direction and between the second direction and the third direction. 13. The vehicle of claim 9 further comprising: electrical leads between the at least one RFIC and each of the plurality of end-fire antennas; and a radar mount having: at least two walls each oriented perpendicular to the first plane and the second plane and having at least one flange configured to support the plurality of end-fi