Bit slicer circuit for s-fsk receiver, integrated circuit, and method associated therewith

1 . A circuit comprising: (a) a signal input adapted to receive spread frequency shift key signals that include mark signals at a mark frequency and that include space signals at a space frequency; (b) mark signal power estimate circuitry having a mark signal input coupled to the signal input and having a mark power estimate output; (c) space signal power estimate circuitry having a space signal input coupled to the signal input and having a space power estimate output; (d) mark signal circuitry having an input coupled to the mark power estimate output and having a mark signal to noise output and having a mark threshold output; (e) space signal circuitry having an input coupled to the space power estimate output and having a space signal to noise output and having a space threshold output; and (f) slicer circuitry having an input coupled to the mark power estimate output, having an input coupled to the mark threshold output, having an input coupled to the space power estimate output, having an input coupled to the space threshold output, and having a digital data output. 2 . The circuit of claim 1 including analog band-pass and anti-aliasing filter circuitry having an input coupled to the signal input and having a filter output coupled to the mark signal input and to the space signal input. 3 . The circuit of claim 1 including an analog to digital converter having an input coupled to the signal input and having a converter output coupled to the mark signal input and to the space signal input. 4 . The circuit of claim 3 including digital demodulator circuitry having a mark input coupled to the converter output, having a space input coupled to the converter output, having a mark demodulator output, and having a space demodulator output. 5 . The circuit of claim 4 in which: the mark signal power estimate circuitry includes mark filter and decimation circuitry having an input coupled to the mark demodulator output and having a mark decimation output; and the space signal power estimate circuitry includes space filter and decimation circuitry having an input coupled to the space demodulator output and having a space decimation output. 6 . The circuit of claim 5 in which: the mark signal power estimate circuitry includes mark combiner circuitry having an input coupled to the mark decimation output, having an input coupled to the space decimation output, and having a mark combined output; and the space signal power estimate circuitry includes space combiner circuitry having an input coupled to the space decimation output, having an input coupled to the mark decimation output, and having a space combined output. 7 . The circuit of claim 6 in which: the mark signal power estimate circuitry includes mark absolute value circuitry having an input coupled to the mark combined output and having an output coupled to the mark power estimate output; and the space signal power estimate circuitry includes space absolute value circuitry having an input coupled to the space combined output and having an output coupled to the space power estimate output. 8 . The circuit of claim 1 including correlator circuitry having an input coupled to the digital data output and having control outputs. 9 . The circuit of claim 8 including keep alive circuitry having an input coupled to the control outputs. 10 . A process comprising: (a) receiving spread frequency shift key signals that include mark signals at a mark frequency and that include space signals at a space frequency; (b) producing mark power estimate signals from the mark signals; (c) producing space power estimate signals from the space signals; (d) producing mark signal to noise signals from the mark signals; (e) producing space signal to noise signals from the space signals; and (f) producing digital data signals from: (i) the mark power estimate signals; (ii) the space power estimate signals; (iii) the mark signal to noise signals; and (iv) the space signal to noise signals. 11 . The process of claim 10 in which the producing digital data signals includes producing Baker sequence digital data signals. 12 . The process of claim 10 in which the producing digital data signals includes producing a sequence of −1, −1, −1, +1, +1, +1, −1, +1, +1, −1, +1 to represent a logic 1. 13 . The process of claim 10 in which the producing digital data signals includes producing a sequence of +1, +1, +1, −1, −1, −1, +1, −1, −1, +1, −1 to represent a logic 0. 14 . The process of claim 10 including correlating the digital data signals and producing control signals. 15 . The process of claim 10 including correlating the digital data signals and controlling a keep alive circuit in response to the digital data signals.