Wideband photonic radio frequency (RF) noise generator

What is claimed is: 1. A photonic random signal generator, comprising: an incoherent optical source configured to generate an optical noise signal, the optical noise signal comprising random signal phases that are uniformly distributed over a pre-determined range of the optical noise signal; a coupler configured to receive the optical noise signal and a delayed version of the optical noise signal and couple the received optical noise signal and the delayed version of the optical noise signal to generate a first coupled signal and a second coupled signal, the first and second coupled signals having a spur free dynamic range (SFDR) based on the uniformly distributed random signal phases of the optical noise signal; a photodetector configured to generate an output signal representative of a phase difference between the optical noise signal and the delayed version of the optical noise signal using the first coupled signal and the second coupled signal; a filter configured to filter the output signal representative of the phase difference to generate an analog random signal; a limiter configured to limit the analog random signal based on a clock signal, to generate a binary digital random signal; a delay circuit configured to receive the analog random signal and generate a delayed analog random signal; a quantizer configured to generate a quantized signal based on an analog combined signal, the analog combined signal based on an input analog signal and the delayed analog random signal; and a digital subtractor configured to generate an output digital signal corresponding to the input analog signal, based on the quantized signal and a multiple bit binary noise signal, wherein the multiple bit binary noise signal corresponds to the binary digital random signal. 2. The photonic random signal generator of claim 1 , wherein the incoherent optical source is a white light emitting diode (LED) source or an amplified spontaneous emissions (ASE) light source with a bandwidth exceeding a bandwidth of a signal of interest. 3. The photonic random signal generator of claim 1 , further comprising: a second filter configured to generate a filtered optical noise signal using the optical noise signal, wherein the coupler is configured to couple the filtered optical noise signal and a delayed version of the filtered optical noise signal to generate the first coupled signal and the second coupled signal. 4. The photonic random signal generator of claim 3 , wherein the filtered optical noise signal comprises a bandwidth exceeding a bandwidth of a signal of interest. 5. The photonic random signal generator of claim 3 , further comprising: a second delay circuit configured to delay a version of the filtered optical noise signal to generate the delayed version of the filtered optical noise signal. 6. The photonic random signal generator of claim 1 , wherein to generate the binary digital random signal, the limiter is configured to: perform a comparison of the analog random signal to a set value at time instances determined by the clock signal; and output a digital value for the binary digital random signal based on the comparison. 7. The photonic random signal generator of claim 1 , further comprising: an adder configured to add the input analog signal and the delayed analog random signal to generate the analog combined signal. 8. A photonic random signal generator, comprising: an incoherent optical source configured to generate an optical noise signal; a coupler configured to couple the optical noise signal and a delayed version of the optical noise signal to generate a first coupled signal and a second coupled signal; a photodetector configured to generate an output signal representative of a phase difference between the optical noise signal and the delayed version of the optical noise signal using the first coupled signal and the second coupled signal; a filter configured to filter the output signal representative of the phase difference to generate an analog random signal; a limiter configured to limit the analog random signal based on a clock signal, to generate a binary digital random signal; a delay circuit configured to receive the analog random signal and generate a delayed analog random signal; a quantizer configured to generate a quantized signal based on an analog combined signal, the analog combined signal based on an input analog signal and the delayed analog random signal; and a digital subtractor configured to generate an output digital signal corresponding to the input analog signal, based on the quantized signal and a multiple bit binary noise signal, wherein the multiple bit binary noise signal corresponds to the binary digital random signal. 9. A method for generating random signals, the method comprising: generating an optical noise signal, the optical noise signal comprising random signal phases that are uniformly distributed over a pre-determined range of the optical noise signal; coupling the optical noise signal and a delayed version of the optical noise signal to generate a first coupled signal and a second coupled signal, the first and second coupled signals having a spur free dynamic range (SFDR) based on the uniformly distributed random signal phases of the optical noise signal; generating an output signal representative of a phase difference between the optical noise signal and the delayed version of the optical noise signal using the first coupled signal and thesecond coupled signal; filtering the output signal representative of the phase difference to generate an analog random signal; limiting the analog random signal based on a clock signal, to generate a binary digital random signal; generating a delayed analog random signal based on the analog random signal; generating a quantized signal based on an analog combined signal, the analog combined signal based on an input analog signal and the delayed analog random signal; and generating an output digital signal corresponding to the input analog signal, based on the quantized signal and a multiple bit binary noise signal, wherein the multiple bit binary noise signal corresponds to the binary digital random signal. 10. The method of claim 9 , further comprising: generating a filtered optical noise signal using the optical noise signal. 11. The method of claim 10 , wherein the coupling comprises: coupling the filtered optical noise signal and a delayed version of the filtered optical noise signal to generate the first coupled signal and the second coupled signal. 12. The method of claim 10 , wherein the filtered optical noise signal comprises a bandwidth exceeding a bandwidth of a signal of interest. 13. The method of claim 11 , further comprising: delaying a version of the filtered optical noise signal to generate the delayed version of the filtered optical noise signal. 14. The method of claim 9 , wherein generating the binary digital random signal comprises: performing a comparison of the analog random signal to 0 at time instances determined by the clock signal; and outputting a digital value for the binary digital random signal based on the comparison. 15. A photonic random signal generator, comprising: an incoherent optical source configured to generate an optical noise signal, the optical noise signal comprising random signal phases that are uniformly distributed over a pre-determined range of the optical noise signal; a first filter configured to generate a filtered optical noise signal using the optical noise signal; a coupler configured to receive the filtered optical noise signal and a delayed version o