Phase demodulation method and circuit

What is claimed is: 1. A method of demodulating a received phase shift keying (PSK) modulated carrier signal, the method comprising: a) splitting the received PSK modulated carrier signal into two analog PSK-modulated signals, each comprising a PSK-modulated carrier wave with a carrier wave frequency f; b) passing a first of the two analog PSK-modulated signals through a multiplying circuit to obtain a frequency-multiplied carrier signal absent of PSK modulation; c) passing the frequency multiplied carrier signal through a first frequency dividing circuit to obtain a first reference carrier wave signal with the carrier wave frequency f; and, d) mixing the first reference carrier wave signal with the second of the two analog PSK-modulated signals using a first electrical signal mixer to obtain a first de-modulated signal therefrom; wherein the method further includes: obtaining, from the frequency-multiplied carrier signal, a second reference carrier wave signal that is phase-shifted relative to the first reference carrier wave signal; and, mixing the second reference carrier wave signal with at least a portion of the second of the two analog PSK-modulated signals using a second electrical signal mixer. 2. The method of claim 1 , wherein b) comprises directing the first of the two analog PSK-modulated signals into two input ports of an electrical signal mixer. 3. The method of claim 1 , wherein c) comprises passing the frequency-multiplied analog carrier signal through an electrical switching circuit that is configured to switch a state thereof in phase with an input signal received by the electrical switching circuit. 4. The method of claim 1 , wherein c) comprises passing the frequency-multiplied carrier signal through a frequency-dividing flip-flop circuit. 5. The method of claim 1 , wherein the received PSK modulated carrier signal comprises a binary PSK (BPSK) modulated signal, and wherein (b) comprises converting the first of the two analog PSK-modulated signals modulated signal into a frequency-doubled signal. 6. The method of claim 1 , further comprising at least one of: passing the frequency-multiplied carrier signal through an edge-sharpening filter, and passing the first reference carrier wave signal through a bandpass filter with a passband including the carrier wave frequency f. 7. The method of claim 1 , wherein the received PSK modulated carrier signal is quadrature-PSK (QPSK) modulated, and wherein: (b) comprises sequentially passing the first of the two analog PSK-modulated signals through two signal squaring circuits for converting into a frequency-quadrupled carrier signal, (c) comprises sequentially passing at least a portion of the frequency quadrupled carrier signal through the first frequency dividing circuit and a second frequency dividing circuit, and wherein the method further comprises: passing a portion of a signal from an output of the first frequency dividing circuit to a third frequency dividing circuit to obtain the second reference carrier wave signal that is phase-shifted with respect to the first reference carrier wave signal by 90°, and obtaining, from the second electrical signal mixer, a second de-modulated signal in quadrature with the first de-modulated signal. 8. The method of claim 1 wherein the received PSK modulated carrier signal is binary-PSK (BPSK) modulated, the method further comprising: passing a portion of the frequency multiplied carrier signal through a second frequency dividing circuit to obtain the second analog reference carrier wave signal that is phase-shifted relative to the first analog reference carrier wave; and, combining output signals from the first and second electrical signal mixers. 9. An electrical circuit for demodulating a received PSK modulated carrier signal that is modulated with a quadrature PSK (QPSK) modulation format, the electrical circuit comprising: a first signal splitter configured to split the received PSK modulated carrier signal into two analog PSK-modulated signals, each comprising a PSK-modulated carrier wave with a carrier wave frequency f that may vary in time; a multiplying circuit disposed to receive a first of the two analog PSK-modulated signals and configured to convert it into a frequency-multiplied carrier signal absent of PSK modulation; a first frequency dividing circuit configured to convert the frequency multiplied carrier signal into a first reference carrier wave signal with the carrier wave frequency f; a first electrical signal mixer configured to mix the first reference carrier wave signal with the second of the two analog PSK-modulated signals to extract a first de-modulated signal therefrom; and, an electrical transmission line connecting the first signal splitter with the first electrical signal mixer; wherein the multiplying circuit comprises two signal squaring circuits connected in series, and wherein the electrical circuit further comprises: a second frequency dividing circuit connected in series with the first frequency dividing circuit; a third frequency dividing circuit connected in parallel with the second frequency dividing circuit and configured to output a second reference carrier wave signal that is shifted in phase relative to the first reference carrier wave signal by 90°; and, a second electrical signal mixer connected to an output of the third frequency dividing circuit for outputting a second de-modulated signal. 10. The electrical circuit of claim 9 , wherein the multiplying circuit comprises an electrical signal mixer. 11. The electrical circuit of claim 9 , wherein the first frequency dividing circuit comprises an electrical switching circuit configured to switch a state thereof in phase with an input signal received by the electrical switching circuit. 12. The electrical circuit of claim 9 , wherein the first frequency dividing circuit comprises a frequency-dividing flip-flop circuit. 13. The electrical circuit of claim 12 , further comprising an edge-sharpening filter disposed operationally between the multiplying circuit and the first frequency dividing circuit. 14. The electrical circuit of claim 9 , wherein the received PSK modulated carrier signal is modulated with a binary PSK (BPSK), and wherein the multiplying circuit comprises a signal squaring circuit. 15. The electrical circuit of claim 9 , further comprising a bandpass filter having a passband including the carrier wave frequency f and disposed operationally between the first frequency dividing circuit and the first electrical signal mixer. 16. The electrical circuit of claim 9 that is integrated in a semiconductor chip. 17. An optical PSK receiver comprising the electrical circuit of claim 9 , the optical PSK receiver further comprising an optical reference source configured for producing an optical reference signal, an optical mixer configured for mixing an input optical PSK modulated signal with the optical reference signal and to output a mixed optical signal, and a photodetector disposed to receive the mixed optical signal for converting thereof into the received PSK modulated carrier signal. 18. An electrical circuit for demodulating a received PSK modulated carrier signal, the electrical circuit comprising: a first signal splitter configured to split the received PSK modulated carrier signal into two analog PSK-modulated signals, each comprising a PSK-modulated carrier wave with a carrier wave frequency f that may vary in time; a multiplying circuit disposed to receive a first of the two analog PSK-modulated signals and configure