Hyperbolic waveform for code-division multiple-access multiple-input multiple-output radar

What is claimed is: 1. A hyperbolic waveform multiple-input multiple-output radar comprising: a generator circuit operable to generate a linear frequency modulated signal and a hyperbolic frequency modulated signal; a plurality of transmit circuits coupled to the generator circuit and operable to generate a plurality of transmit signals by analog mixing the linear frequency modulated signal and the hyperbolic frequency modulated signal in response to a plurality of coding family parameters, wherein the plurality of transmit signals define an orthogonal family of waveforms; a multiple-input multiple-output antenna coupled to the plurality of transmit circuits and operable to transmit the plurality of transmit signals toward an object and receive a plurality of receive signals from the object; and a plurality of receive circuits coupled to the multiple-input multiple-output antenna and operable to determine a plurality of data signals in response to the plurality of coding family parameters within the plurality of receive signals, wherein the plurality of data signals are suitable to determine a distance between the multiple-input multiple-output antenna and the object. 2. The hyperbolic waveform multiple-input multiple-output radar according to claim 1 , wherein the orthogonal family of waveforms define a plurality of code-division multiple access codewords. 3. The hyperbolic waveform multiple-input multiple-output radar according to claim 1 , wherein the generator circuit and the plurality of transmit circuits are characterized by an absence of digital-to-analog converters. 4. The hyperbolic waveform multiple-input multiple-output radar according to claim 1 , further comprising a radar processing unit coupled to the plurality of receive circuits and operable to determine the distance between the multiple-input multiple-output antenna and the object. 5. The hyperbolic waveform multiple-input multiple-output radar according to claim 1 , wherein each of the plurality of transmit circuits comprises a first frequency circuit configured to generate a weighted linear frequency modulated signal by frequency weighting or phase weighting the linear frequency modulated signal by a first coding family parameter of the plurality of coding family parameters, and the first coding family parameter has a value of unity or less. 6. The hyperbolic waveform multiple-input multiple-output radar according to claim 5 , wherein each of the plurality of transmit circuits comprises a second frequency circuit configured to generate a weighted hyperbolic frequency modulated signal by frequency weighting or phase weighting the hyperbolic frequency modulated signal by difference between unity and the value of the first coding family parameter. 7. The hyperbolic waveform multiple-input multiple-output radar according to claim 6 , wherein each of the plurality of transmit circuits further comprises an analog mixer circuit configured to generate an internal transmit signal by mixing the weighted linear frequency modulated signal and the weighted hyperbolic frequency modulated signal. 8. The hyperbolic waveform multiple-input multiple-output radar according to claim 7 , wherein each of the plurality of transmit circuits further comprising a frequency mixer circuit configured to generate one of the plurality of transmit signals by multiplying the internal transmit signal by a local oscillator signal. 9. The hyperbolic waveform multiple-input multiple-output radar according to claim 1 , wherein the multiple-input multiple-output antenna is mounted on a vehicle. 10. A method for range determination with a hyperbolic waveform multiple-input multiple-output radar, comprising: generating a linear frequency modulated signal; generating a hyperbolic frequency modulated signal; generating a plurality of transmit signals by analog mixing the linear frequency modulated signal and the hyperbolic frequency modulated signal in response to a plurality of coding family parameters using a plurality of analog circuits, wherein the plurality of transmit signals form an orthogonal family of waveforms; transmitting the plurality of transmit signals toward an object using a multiple-input multiple-output antenna; receiving a plurality of receive signals from the object; generating a plurality of data signals in response to the plurality of coding family parameters within the plurality of receive signals; and calculating a distance between the multiple-input multiple-output antenna and the object in response to the data signals. 11. The method according to claim 10 , wherein the orthogonal family of waveforms define a plurality of code-division multiple access codewords. 12. The method according to claim 10 , wherein the generation of the linear frequency modulation signal, the generation of the hyperbolic frequency modulation signal, and the generation of the plurality of transmit signals are characterized by an absence of digital-to-analog conversion. 13. The method according to claim 10 , wherein the generation of the plurality of transmit signals includes generating a plurality of weighted linear frequency modulated signals by frequency weighting or phase weighting the linear frequency modulated signal in response to the plurality of coding family parameters, and the plurality of coding family parameters have a plurality of values of unity or less. 14. The method according to claim 13 , wherein the generation of the plurality of transmit signals includes generating a plurality of weighted hyperbolic frequency modulated signals by frequency weighting or phase weighting the hyperbolic frequency modulated signal by a plurality of differences between unity and the plurality of values of the plurality of coding family parameters. 15. The method according to claim 14 , wherein the generation of the plurality of transmit signals includes generating a plurality of internal transmit signals by mixing the plurality of weighted linear frequency modulated signals and the plurality of weighted hyperbolic frequency modulated signals. 16. The method according to claim 15 , wherein the generation of the plurality of transmit signals includes multiplying the plurality of internal transmit signals by a local oscillator signal. 17. A vehicle comprising: a generator circuit mounted to the vehicle and operable to generate a linear frequency modulated signal and a hyperbolic frequency modulated signal; a plurality of transmit circuits mounted to the vehicle and operable to generate a plurality of transmit signals by analog mixing the linear frequency modulated signal and the hyperbolic frequency modulated signal in response to a plurality of coding family parameters, wherein the plurality of transmit signals define an orthogonal family of waveforms; a multiple-input multiple-output antenna mounted to the vehicle and operable to transmit the plurality of transmit signals toward an object and receive a plurality of receive signals from the object; and a plurality of receive circuits mounted to the vehicle and operable to generate a plurality of data signals in response to the plurality of coding family parameters within the plurality of receive signals, wherein the plurality of data signals are suitable to determine a distance between the vehicle and the object. 18. The vehicle according to claim 17 , wherein the orthogonal family of waveforms define a plurality of code-division multiple access codewords. 19. The vehicle according to claim 17 , wherein the generator circuit and the plurality of transmit circu