A crystal oscillator is coupled to a digital automatic gain control (AGC) having oscillation detection and amplitude control loops. The oscillation detection loop may increase the transconductance (gm) of the oscillator transistor until oscillation is detected therefrom. Then the amplitude control loop detects the amplitudes of oscillations from the crystal oscillator, compares these amplitudes to high and low voltage references and generates digital signals to find a critical transconductance (gm) for an oscillator amplifier and control this gm to maintain a constant oscillation waveform amplitude therefrom. An up/down counter defines the servo control loop bandwidth/update-rate according to an update clock rate thereto. Loop stability is achieved when the control loop bandwidth is less than the start-up time required for the oscillation envelope of the crystal oscillator to grow for oscillation. An oscillator failure detector may also be provided.

A reconfigurable crystal oscillator and a method for reconfiguring a crystal oscillator are provided. The reconfigurable crystal oscillator includes a transconductance circuit, a feedback resistor, a crystal tank, an input-end capacitor and an output-end capacitor. Both of the feedback resistor and the crystal tank are coupled between an input terminal and an output terminal of the transconductance circuit. The input-end capacitor is coupled to the input terminal of the transconductance circuit, and the output-end capacitor is coupled to the output terminal of the transconductance circuit. In particular, the transconductance circuit is configured to provide a transconductance, and when an operation mode of the reconfigurable crystal oscillator is switched, an input-end capacitance of the input-end capacitor and an output-end capacitance of the output-end capacitor are switched, respectively.

In certain aspects, an apparatus includes a transformer including an input inductor and an output inductor, wherein the input inductor is magnetically coupled to the output inductor. The apparatus also includes a transconductance driver configured to drive the input inductor based on an input signal. The apparatus further includes a feedback circuit configured to detect an output voltage swing at the output inductor, generate a regulated voltage at the input inductor, and control the regulated voltage based on the detected output voltage swing.

An output buffer for an oscillator circuit and associated methodology. The output buffer has inverters and at least one negative feedback loop coupled to corresponding inverters. The negative feedback loop of the circuit is disabled in response to a control signal until one or more of a defined level of oscillation and a defined period of time is reached during start-up of the oscillator circuit, and is thereafter enabled. At least one of the inverters has at least one second negative feedback loop coupled to the corresponding inverter. An amount of feedback provided by the second negative feedback loop is adjustable in response to a control signal, where a first feedback level is present until a defined level of oscillation and/or a defined period of time is reached during start-up, a second feedback level is thereafter present in, and the first feedback level is less than the second feedback level.

An oscillator start-up circuit and methodology for oscillator start-up is disclosed. The circuit includes a reference bias switch coupled to a reference node and a load node of a transconductor of an oscillator. The reference bias switch is responsive to a control signal for start-up of the oscillator and operable to close at a first time prior to start-up of the oscillator to maintain a voltage at the reference node equal to a voltage at the load node prior to application of bias to the transconductor. The reference bias switch is further operable to open at a second time subsequent to the first time. In one embodiment, a separate reference bias voltage is applied to a reference node of the transconductor.

In certain aspects, an apparatus includes a transformer including an input inductor and an output inductor, wherein the input inductor is magnetically coupled to the output inductor. The apparatus also includes a transconductance driver configured to drive the input inductor based on an input signal. The apparatus further includes a feedback circuit configured to detect an output voltage swing at the output inductor, generate a regulated voltage at the input inductor, and control the regulated voltage based on the detected output voltage swing.

An oscillator bias stabilization circuit and method for biasing the circuit is disclosed. The bias stabilization circuit includes a plurality of resistive dividers responsive to a control signal in the circuit. The plurality of resistive dividers are selectably connectable in the circuit to provide an adaptable equivalent resistance in response to a control signal while keeping a bias voltage produced by the circuit substantially constant as the loop gain of an oscillator is varied. The plurality of resistive dividers are coupled to a node in the oscillator that establishes the bias voltage.

An oscillator start-up circuit and methodology for oscillator start-up is disclosed. The circuit includes a reference bias switch coupled to a reference node and a load node of a transconductor of an oscillator. The reference bias switch is responsive to a control signal for start-up of the oscillator and operable to close at a first time prior to start-up of the oscillator to maintain a voltage at the reference node equal to a voltage at the load node prior to application of bias to the transconductor. The reference bias switch is further operable to open at a second time subsequent to the first time. In one embodiment, a separate reference bias voltage is applied to a reference node of the transconductor.

An output buffer for an oscillator circuit and associated methodology. The output buffer has inverters and at least one negative feedback loop coupled to corresponding inverters. The negative feedback loop of the circuit is disabled in response to a control signal until one or more of a defined level of oscillation and a defined period of time is reached during start-up of the oscillator circuit, and is thereafter enabled. At least one of the inverters has at least one second negative feedback loop coupled to the corresponding inverter. An amount of feedback provided by the second negative feedback loop is adjustable in response to a control signal, where a first feedback level is present until a defined level of oscillation and/or a defined period of time is reached during start-up, a second feedback level is thereafter present in, and the first feedback level is less than the second feedback level.

An oscillator bias stabilization circuit and method for biasing the circuit is disclosed. The bias stabilization circuit includes a plurality of resistive dividers responsive to a control signal in the circuit. The plurality of resistive dividers are selectably connectable in the circuit to provide an adaptable equivalent resistance in response to a control signal while keeping a bias voltage produced by the circuit substantially constant as the loop gain of an oscillator is varied. The plurality of resistive dividers are coupled to a node in the oscillator that establishes the bias voltage.