Multimode communication and radar system resource allocation

What is claimed is: 1. A wireless multimode system comprising: a modem configured to be coupled to an array of N antenna elements, the array comprising a first portion of M antenna elements and a second portion of L antenna elements, the second portion being different than the first portion, wherein N, M and L are positive integers greater than zero, and wherein M plus L is lower than or equal to N, wherein the modem is configured to: provide transmit radar signals and transmit communication signals within frames of transmit data based on one or more predetermined parameters for transmission to the M antenna elements, receive, from the M antenna elements, frames of receive data, wherein the frames of receive data comprises receive communication signals, wherein the transmit communication signals and the receive communication signals form a communication link, receive, from the second portion of L antenna elements, receive radar signals, wherein the receive radar signals corresponds to the transmit radar signals; a resource scheduler configured to allocate bandwidth for the transmit radar signals and the transmit communication signals within the frames of transmit data based on the one or more predetermined parameters; and a controller configured to change a partitioning of the first portion of the M antenna elements and the second portion of the L antenna elements. 2. The wireless multimode system of claim 1 , wherein each frame comprises P sub-frames, each sub-frame comprising Q time slots, each time slot comprising R frequency bands, wherein the resource scheduler is configured to, when allocating a first time slot to radar signals, allocating the R frequency bands of the first time slot to the radar signals, wherein P, Q and R and positive integers greater than zero. 3. The wireless multimode system of claim 2 , wherein each frame of transmit data comprises P sub-frames, each sub-frame comprising Q time slots, each time slot comprising R frequency bands, wherein the resource scheduler is configured to, when allocating a time slots to the transmit radar signals, allocating more than one consecutive time slots to the radar signals, wherein P, Q and R and positive integers greater than zero. 4. The wireless multimode system of claim 2 , wherein R frequency bands correspond to 12 orthogonal frequency division multiplexing (OFDM) sub-carriers. 5. The wireless multimode system of claim 1 , wherein the one or more predetermined parameters comprises an amount of traffic in the communication link, a priority queue associated with the communication link or a signal-to-noise ratio of the communication link. 6. The wireless multimode system of claim 1 , wherein the one or more predetermined parameters comprises quality of service (QOS) parameters or radio channel quality. 7. The wireless multimode system of claim 1 , wherein the one or more predetermined parameters comprises a maximum period for transmitting transmit radar signals. 8. The wireless multimode system of claim 7 , wherein the maximum period for transmitting the transmit radar signals is about 5 ms. 9. The wireless multimode system of claim 1 , further comprising RF transceiver circuitry configured to transmit and receive RF signals to and from the M antenna elements in a first frequency band and receive RF signals from the L antenna elements in a second frequency band different from the first frequency band. 10. The wireless multimode system of claim 1 , wherein the transmit radar signals comprises PRBS, FSK or COSTAS waveforms. 11. The wireless multimode system of claim 1 , wherein the controller is configured to select a type of waveform from a radar waveform set to be used as radar signals when allocating a first time slot to radar signals, wherein the radar waveform set comprises FSK radar signals, and wherein the controller comprises the resource scheduler. 12. The wireless multimode system of claim 1 , wherein M is equal to L. 13. The wireless multimode system of claim 1 , wherein M plus L is equal to N. 14. The wireless multimode system of claim 1 , further comprising a controller configured to partition the array of N antenna elements into the M antenna elements and the L antenna elements. 15. The wireless multimode system of claim 1 , further comprising the array of N antenna elements. 16. A method comprising: providing transmit radar signals and transmit communication signals within frames of transmit data based on one or more predetermined parameters for transmission to M antenna elements of an array of N antenna elements; receiving, from the M antenna elements, frames of receive data, wherein the frames of receive data comprises receive communication signals, wherein the transmit communication signals and the receive communication signals form a communication link, and receiving, from L antenna elements of the array of N antenna elements different from the M antenna elements, receive radar signals, wherein the receive radar signals corresponds to the transmit radar signals, wherein N, M and L are positive integers greater than zero, and wherein M plus L is lower than or equal to N; allocating bandwidth for transmit radar signals and transmit communication signals within the frames of transmit data based on the one or more predetermined parameters; and changing a partitioning of the M antenna elements and the L antenna elements. 17. The method of claim 16 , further comprising partitioning the array of N antenna elements into the M antenna elements and the L antenna elements. 18. A method for operating a wireless multimode system, the method comprising: receiving data to be transmitted, the data comprising user communication data and radar waveforms; receiving information of a communication link associated with a first portion of an antenna array of the wireless multimode system; allocating bandwidth of frames to be transmitted by the first portion of the antenna array between the user communication data and the radar waveforms based on the received information of the communication link; transmitting the frames via the first portion of the antenna array; receiving reflected frames via a second portion of the antenna array, the second portion being different than the first portion, the reflected frames corresponding to the transmitted frames; retrieving reflected radar waveforms from the received reflected frames; determining a location of a target based on the retrieved reflected radar waveforms; and changing a partitioning of antenna elements of the first portion of the antenna array and antenna elements of the second portion of the antenna array. 19. The method of claim 18 , further comprising: monitoring communication traffic of the communication link; and when communication traffic level is below a threshold, turning off the second portion of the second portion of the antenna array. 20. The method of claim 18 , further comprising: monitoring communication traffic of the communication link; and when communication traffic level is below a threshold, stop allocating bandwidth of the frames to be transmitted to radar waveforms while continue allocating the bandwidth of the frames to be transmitted to user communication data.