Self enabling signal conditioner for conditioning a crystal oscillator output signal into a compliant clock signal

The invention claimed is: 1. A signal conditioner for conditioning a differential oscillation signal into a compliant clock signal, comprising: a first signal path that toggles a first binary signal in response to the differential oscillation signal when the differential oscillation signal reaches a small amplitude level; a second signal path that toggles a second binary signal in response to the differential oscillation signal only when the differential oscillation signal reaches a large amplitude level that is greater than said small amplitude level; and a coincident gate having a first input receiving said first binary signal, a second input receiving said second binary signal, and an output for providing the clock signal, wherein said coincident gate toggles the clock signal high only when said first binary signal and said second binary signal are both high, and toggles the clock signal low only when said first binary signal and said second binary signal are both low. 2. The signal conditioner of claim 1 , wherein said first signal path comprises a first set-reset latch that toggles said first binary signal when the differential oscillation signal is at least said small amplitude level, and wherein said second signal path comprises a second set-reset latch that toggles said second binary signal only when the differential oscillation signal is at least said large amplitude level. 3. The signal conditioner of claim 2 , wherein said first set-reset latch comprises a first pair of cross-coupled NAND logic gates each comprising a symmetric CMOS configuration, and wherein said second set-reset latch comprises a second pair of cross-coupled NAND logic gates each comprising an asymmetric CMOS configuration. 4. The signal conditioner of claim 1 , wherein said first signal path comprises symmetrically configured transistors and wherein said second signal path comprises asymmetrically configured transistors. 5. The signal conditioner of claim 1 , wherein said first signal path is configured with a first propagation delay, wherein said second signal path is configured with a second propagation delay, wherein said second propagation delay is longer than said first propagation delay, and wherein a difference between said first and second propagation delays ensures that said first and second binary signals do not transition simultaneously. 6. The signal conditioner of claim 1 , wherein said second signal path inverts said second binary signal relative to said first binary signal. 7. The signal conditioner of claim 6 , wherein said second signal path further comprises a delay circuit that ensures that said second binary signal transitions after transitioning of said first binary signal. 8. The signal conditioner of claim 1 , wherein when the differential oscillation signal reaches said large amplitude level causing jitter of said second binary signal based on a metastable period, said first binary signal next transitions after expiration of said metastable period. 9. The signal conditioner of claim 1 , wherein said coincident gate comprises: a first AND logic gate having a first input receiving said first binary signal, a second input receiving the clock signal, and an output providing a first digital signal; a second AND logic gate having a first input receiving said first binary signal, a second input receiving said second binary signal, and an output providing a second digital signal; a third AND logic gate having a first input receiving said second binary signal, a second input receiving the clock signal, and an output providing a third digital signal; a NOR logic gate having inputs receiving said first, second and third digital signals and an output providing an inverted clock signal; and an inverter having an input receiving said inverted clock signal and an output for providing the clock signal. 10. The signal conditioner of claim 1 , wherein said coincident gate comprises: a first pair of PMOS transistors having current terminals coupled in series between a source voltage and an intermediate node and having gate terminals receiving said first and second binary signals; a second pair of PMOS transistors having current terminals coupled in series between said source voltage and said intermediate node and having gate terminals receiving said first binary signal and a feedback signal; a third pair of PMOS transistors having current terminals coupled in series between said source voltage and said intermediate node and having gate terminals receiving said second binary signal and said feedback signal; a first pair of NMOS transistors having current terminals coupled in series between said intermediate node and a reference node and having gate terminals receiving said first and second binary signals; a second pair of NMOS transistors having current terminals coupled in series between said intermediate node and said reference node and having gate terminals receiving said first binary signal and said feedback signal; a third pair of NMOS transistors having current terminals coupled in series between said intermediate node and said reference node and having gate terminals receiving said second binary signal and said feedback signal; a first CMOS transistor pair comprising a first PMOS transistor having current terminals coupled between said source voltage and a feedback node developing said feedback signal and a first NMOS transistor having current terminals coupled between said feedback node and said reference node, and having gate terminals coupled to said intermediate node; and a second CMOS transistor pair comprising a second PMOS transistor having current terminals coupled between said source voltage and an output node developing the clock signal and a first NMOS transistor having current terminals coupled between said output node and said reference node, and having gate terminals coupled to said intermediate node. 11. An electronic system, comprising: a crystal oscillator that provides a differential oscillation signal; a signal conditioner that conditions said differential oscillation signal into a compliant clock signal, comprising: a firing circuit that toggles a digital fire signal in response to said differential oscillation signal when said differential oscillation signal reaches a small amplitude level; an arming circuit that toggles a digital arm signal in response to said differential oscillation signal only when said differential oscillation signal reaches a large amplitude level that is greater than said small amplitude level; and a hysteresis flip-flop having a first input receiving said digital fire signal, a second input receiving said digital arm signal, and an output for providing said clock signal, wherein said hysteresis flip-flop toggles said clock signal high only when said digital fire signal and said digital arm signal are both high, and toggles said clock signal low only when said digital fire signal and said digital arm signal are both low; and a reset de-assertion synchronizer having a first input receiving an asynchronous reset signal, having a second input receiving said clock signal, and having an output providing a synchronous reset signal that is asserted when said asynchronous reset signal is asserted and that is de-asserted synchronous with said clock signal after said asynchronous reset signal is de-asserted. 12. The electronic system of claim 11 , further comprising a target system including at least one system flip-flop having a clock input receiving said clock signal and having a reset input receiving said synchronous reset signal. 13. The electronic system of claim 11 , wherein said arming circuit comprises an a