Radar apparatus and method

The invention claimed is: 1. A radar apparatus comprising: a transmitter antenna that transmits a frequency modulated transmit signal having a transmit bandwidth towards a scene potentially comprising two or more targets, a receiver antenna that receives a receive signal reflected from said scene in response to the transmission of said transmit signal, a mixer that mixes said receive signal with said transmit signal to obtain a mixed receive signal, sampling circuitry that samples said mixed receive signal to obtain receive signal samples from a period of said receive signal, a processor that processes said receive signal samples by defining a measurement matrix assuming the receive signal were received in response to a frequency modulated transmit signal having an assumed bandwidth that is higher than said actual transmit bandwidth, said assumed bandwidth corresponding to a desired range resolution, and that determines the positions of one or more targets of the scene by applying compressive sensing using said measurement matrix and said receive signal samples, and a post-processor that groups together receive signal samples having a depth within the same depth bin and belonging to the same target. 2. The radar apparatus as claimed in claim 1 , wherein said processor is configured to define said measurement matrix having a number of rows corresponding to the number of receive signal samples from a period of said receive signal, wherein the elements of each row have a value that depends on the same frequency component of said receive signal, and having a number of columns corresponding to a defined range grid that matches the desired range resolution. 3. The radar apparatus as claimed in claim 1 , wherein said processor is configured to apply a l1-norm minimization algorithm for solving a l1-regularization problem existing when applying compressive sensing. 4. The radar apparatus as claimed in claim 3 , wherein said processor is configured to solve said l1-regularization problem by applying a second order cone solver. 5. The radar apparatus as claimed in claim 1 , wherein said processor is configured to apply a l1-norm minimization algorithm for solving a l1-regularization problem in the form min∥ s∥ 1 s.t.∥Φx−y∥ 2 ≦ε wherein s is the desired solution for the reflectivity vector of the one or more targets, Φ is the measurement matrix, x represents a signal to be recovered, y is a vector of the receive signal samples from a period of said receive signal and ε represents an accepted error parameter for use as stop criterion for said minimization algorithm. 6. The radar apparatus as claimed in claim 1 , wherein said processor is configured to apply a l1-norm minimization algorithm for solving a l1-norm regularization problem in the form min∥ s∥ 1 s.t.∥Φ H (Φ s−y )∥ ∞ ≦μ wherein s is the desired solution for the reflectivity vector of the one or more targets, Φ is the measurement matrix, Φ H is the Hermitian transpose of said matrix, y is a vector of the receive signal samples from a period of said receive signal and μ is a regularization parameter. 7. The radar apparatus as claimed in claim 6 , wherein said processor is configured to iteratively adjust the value of said regularization parameter, solve the l1-regularization problem with the adjusted regularization value and update the values of the detected targets until an end criterion is fulfilled. 8. The radar apparatus as claimed in claim 7 , wherein said processor is configured to iteratively adjust said regularization value by decreasing is with increasing iteration number, in particular as μ j =  Φ H ⁢ y  ∞ - max i = 0 ⁢ … ⁢ ⁢ M - 1 ⁢  ϕ i  ∞ ⁢ 2 · log ⁢ ⁢ N ⁢ ⁢ σ 2 1.1 · 2 j - 1 wherein Φ is the measurement matrix, σ 2 is the noise variance, N is the number of receive signal samples from a period of said receive signal, M is the number or range grid positions, and j is the iteration number. 9. The radar apparatus as claimed in claim 7 , wherein said processor is configured to iteratively normalize, weight and accumulate the estimated values for the reflectivity vector after the l1-regularization problem is solved and before the end criterion is checked. 10. The radar apparatus as claimed in claim 9 , wherein said processor is configured to give more penalty to estimated target values obtained with a higher value of the regularization parameter. 11. The radar apparatus as claimed in claim 1 , further comprising a FFT unit that performs a FFT on the mixed receive signal to obtain an FFT receive signal and a selection unit that selects regions of the scene in which potential targets are located by analyzing said FFT values of the receive signal, wherein said processor is configured to process said receive signal samples and define a measurement matrix on a grid having a higher range resolution than the theoretical range resolution only for the selected regions and to determine the positions of one or more targets by applying compressive sensing only within the selected regions of the scene. 12. The radar apparatus as claimed in c