Single-point radar cross section approaches for radar simulation

What is claimed is: 1 . A method comprising: determining, over a plurality of target ranges, antenna responses obtained with an electromagnetic sensor that is positioned in free space; determining, for the plurality of target ranges, multi-path effects and near-field effects on the electromagnetic sensor when located on a vehicle; based on the antenna responses with the multi-path effects and the near-field effects, generating a response map of expected responses for the electromagnetic sensor given a plurality of single-point locations proximate the vehicle, each expected response accounting for a corresponding angular and range dependent ground effect determined for that single-point location; and outputting the response map to a sensor simulator configured to test detection accuracy of a simulated object located at a particular single-point location given the expected response defined by the response map for that particular single-point location. 2 . The method of claim 1 , wherein the expected responses each include a target radar cross section adjusted for the corresponding angular and range dependent ground effect determined for that single-point target location. 3 . The method of claim 2 , wherein the target radar cross section for each of the expected responses is dependent on a target angle and target range between the vehicle and that single-point target location. 4 . The method of claim 2 , wherein the expected responses each have a target signal to noise ratio that is greater than a detection threshold of the electromagnetic sensor. 5 . The method of claim 1 , wherein determining the antenna responses comprises: collecting the antenna responses determined for each of the target ranges and for a plurality of angular intervals arranged about the vehicle. 6 . The method of claim 5 , wherein collecting the antenna responses comprises: adjusting a ray launcher and ray tracer to step through range and angle adjustments for collecting the antenna responses in angular intervals for each of the target ranges. 7 . The method of claim 1 , further comprising: determining, based on the antenna responses, a set of response fluctuations for the electromagnetic sensor at each of the target ranges; and generating the response map from applying the set of response fluctuations determined for each of the target ranges with the multi-path effects and the near-field effects simulated for that target range. 8 . The method of claim 7 , wherein determining the multi-path effects and near-field effects on the electromagnetic sensor when located on the vehicle comprises: using a multi-path model to account for multiple propagation paths of electromagnetic signals obtained by the electromagnetic sensor at each of the target ranges to determine a combination of the response fluctuations caused by the multiple propagation paths at each of the target ranges. 9 . The method of claim 8 , wherein the multi-path model comprises a four-path model to account for a direct-direct propagation path, a direct-indirect propagation path, an indirect-direct propagation path, and an indirect-indirect propagation path. 10 . The method of claim 8 , wherein the combination of the response fluctuations caused by the multiple propagation paths at each of the target ranges is used to determine the corresponding angular and range dependent ground effects to be applied to the expected responses defined in the response map. 11 . The method of claim 1 , wherein the electromagnetic sensor comprises a radar, and the sensor simulator comprises a radar simulator. 12 . The method of claim 11 , wherein the radar simulator is configured to test performance of radar hardware or radar software in detecting the simulated object given the expected response for the simulated object as defined by the response map for that particular single-point location. 13 . The method of claim 1 , wherein outputting the response map to the sensor simulator comprises: providing the response map to an environmental response data interface of the sensor simulator, the data interface transforming the expected responses defined by the response map into environmental response data for enabling the sensor simulator to simulate electromagnetic returns from simulated objects by uniquely accounting for the corresponding angular and range dependent ground effects defined by the response map for each simulated object location. 14 . The method of claim 1 , wherein outputting the response map to the sensor simulator comprising outputting the response map to configure the sensor simulator to test the detection accuracy of the simulated object at that particular single-point location from processing the expected response defined by the response map for that particular single-point location. 15 . The method of claim 1 , further comprising: outputting the response map to another sensor simulator configured to test detection accuracy of another simulated object that appears at multiple single-point locations based on the expected response defined by the response map for each of the multiple single-point locations. 16 . The method of claim 1 , further comprising: outputting the response map to another sensor simulator configured to test whether the electromagnetic sensor accurately detects a simulated object having a first surface that is occluded or has directivity influenced by a second surface based on a group of the expected responses defined by the response map for each of the single-point locations on the first surface separate from the expected response defined by the response map for each of the single-point locations on the second surface. 17 . A non-transitory storage media comprising instruction that, when executed, cause at least one processor to: determine, over a plurality of target ranges, antenna responses obtained with an electromagnetic sensor that is positioned in free space; determine, for the plurality of target ranges, multi-path effects and near-field effects on the electromagnetic sensor when located on a vehicle; based on the antenna responses with the multi-path effects and the near-field effects, generate a response map of expected responses for the electromagnetic sensor given a plurality of single-point locations proximate the vehicle, each expected response accounting for a corresponding angular and range dependent ground effect determined for that single-point location; and output, by the processor, the response map to a sensor simulator configured to test the detection accuracy of a simulated object located at a particular single-point location given the expected response defined by the response map for that particular single-point location. 18 . A system comprising at least one processor configured to: determine, over a plurality of target ranges, antenna responses obtained with an electromagnetic sensor that is positioned in free space; determine, for the plurality of target ranges, multi-path effects and near-field effects on the electromagnetic sensor when located on a vehicle; based on the antenna responses with the multi-path effects and the near-field effects, generate a response map of expected responses for the electromagnetic sensor given a plurality of single-point locations proximate the vehicle, each expected response accounting for a corresponding angular and range dependent ground effect determined for that single-point location; and output, by the processor, the response map to a sensor simulator configured to test the detection accuracy of a si