Detection for localizing a particle

The invention claimed is: 1. A detection method for localizing at least one particle moving in a flow, the detection method comprising: emitting a transmission signal by a transmitter of a detection device; receiving a reflected reception signal, wherein the reflected reception signal is frequency-modulated and phase-modulated in comparison with the transmission signal, by a receiver of the detection device; convolving, by an evaluation unit of the detection device, the reflected reception signal with at least one kernel, wherein the at least one kernel is representative of a conjugate estimated channel pulse response, to form a reconstructed particle position function; and determining, by the evaluation unit of the detection device, a position of the particle from the reconstructed particle position function. 2. The detection method of claim 1 , wherein the convolution is carried out multiple times, each with a different kernel of a plurality of kernels, wherein each kernel of the plurality of kernels corresponds to a different expected particle position function, and wherein particle position is determined from the plurality of reconstructed particle position functions. 3. The detection method of claim 2 , wherein each kernel of the at least one kernel is assigned to particle position functions of the particle, wherein the particle position functions are distributed along a principal movement direction of the flow. 4. The detection method of claim 3 , wherein determining the position further comprises: superpositioning the plurality of reconstructed particle position functions into a two-dimensional or three-dimensional image in spatial coordinates. 5. The detection method of claim 3 , wherein the detection method is applied to a plurality of particles in the particle flow, the method further comprising: extracting associated positions of the plurality of particles based on an assumed predetermined statistically-dependent distribution; and mapping the extracted associated positions of the plurality of particles onto a probability function. 6. The detection method of claim 3 , further comprising: selecting the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel to have a complex value. 7. The detection method of claim 3 , further comprising: spectrally tapering the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel. 8. The detection method of claim 2 , wherein determining the position further comprises: superpositioning the plurality of reconstructed particle position functions into a two-dimensional or three-dimensional image in spatial coordinates. 9. The detection method of claim 8 , wherein the detection method is applied to a plurality of particles in the particle flow, the method further comprising: extracting associated positions of the plurality of the plurality of particles based on an assumed predetermined statistically-dependent distribution; and mapping the extracted associated positions of particles onto a probability function. 10. The detection method of claim 8 , further comprising: selecting the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel to have a complex value. 11. The detection method of claim 2 , wherein the detection method is applied to a plurality of particles in the particle flow, the method further comprising: extracting associated positions of the plurality of particles based on an assumed predetermined statistically-dependent distribution; and mapping the extracted associated positions of the plurality of particles onto a probability function. 12. The detection method of claim 2 , further comprising: selecting the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel to have a complex value. 13. The detection method of claim 2 , further comprising: spectrally tapering the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel. 14. The detection method of claim 1 , wherein the detection method is applied to a plurality of particles in the particle flow, the method further comprising: extracting associated positions of the plurality of particles based on an assumed predetermined statistically-dependent distribution; and mapping the extracted associated positions of the plurality of particles onto a probability function. 15. The detection method of claim 14 , further comprising: determining whether the particle flow includes an inhomogeneous distribution of particles based on the probability function; and localizing the inhomogeneity based on at least one maximum of the probability function, wherein the at least one maximum includes an absolute maximum. 16. The detection method of claim 15 , further comprising: selecting the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel to have a complex value. 17. The detection method of claim 14 , further comprising: selecting the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel to have a complex value. 18. The detection method of claim 1 , further comprising: spectrally tapering the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel. 19. The detection method of claim 18 , further comprising: high-pass filtering the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel. 20. The detection method of claim 1 , further comprising: selecting the reflected reception signal, the at least one kernel, or the reflected reception signal and the at least one kernel to have a complex value.