Crystal driver circuit with core amplifier having unbalanced tune capacitors

The invention claimed is: 1. A crystal driver circuit for driving a crystal to oscillate at a resonant frequency, comprising: an amplifier input node and an amplifier output node for coupling across the crystal; an amplifier having an input coupled to said amplifier input node and having an output coupled to said amplifier output node; a current source that provides a core bias current to said amplifier; and a first tune capacitor coupled between said amplifier output node and a reference node and having a first capacitance, and a second tune capacitor coupled between said amplifier input node and said reference node and having a second capacitance, wherein said first capacitance is greater than said second capacitance by a capacitance offset that has been determined to minimize frequency shift over an operating temperature range of the crystal driver circuit; wherein said capacitance offset is maintained during operation of the crystal driver circuit regardless of any change in temperature throughout said operating temperature range of the crystal driver circuit. 2. The crystal driver circuit of claim 1 , wherein: said first tune capacitor is adjustable and has and adjust input; wherein said second tune capacitor is adjustable and has an adjust input; and further comprising a controller coupled to said adjust input of each of said first and second tune capacitors. 3. The crystal driver circuit of claim 2 , further comprising a memory coupled to said controller that stores an offset value indicative of said capacitance offset, and wherein said controller uses said offset value to set said first and second capacitances. 4. The crystal driver circuit of claim 2 , wherein each of said first and second tune capacitors comprises a plurality of capacitors and a corresponding plurality of switches, and wherein said controller controls said plurality of switches for selecting from among said plurality of capacitors. 5. The crystal driver circuit of claim 4 , wherein said plurality of capacitors are organized as a binary progression of capacitances based on a nominal capacitance value and wherein said controller provides a digital code to control said plurality of switches for selecting a corresponding one of said first and second capacitances as a multiple of said nominal capacitance value. 6. The crystal driver circuit of claim 4 , further comprising a balance capacitor coupled between said first and second capacitor terminals having a capacitance that compensates for a difference between parasitic capacitances of said amplifier input node and said amplifier output node. 7. The crystal driver circuit of claim 1 , further comprising a controller that adjusts said first tune capacitor and said second tune capacitor together in the same direction up or down to achieve a target frequency level while maintaining said capacitance offset between said first capacitance and said second capacitance. 8. The crystal driver circuit of claim 1 , further comprising a controller that retrieves said capacitance offset from a memory and increases said first capacitance from a nominal value by half of said capacitance offset and decreases said second capacitance from said nominal value by half of said capacitance offset to establish initial capacitances of said first and second tune capacitors. 9. The crystal driver circuit of claim 1 , wherein said capacitance offset is selected from a plurality of capacitance offsets, wherein each of said plurality of capacitance offsets is tested at room temperature to achieve a target frequency and target amplitude and then tested to determine a corresponding frequency deviation that is measured over a plurality of temperatures below and above said room temperature within said operating temperature range, and wherein said capacitance offset is selected from among said plurality of capacitance offsets as having the least minimum frequency deviation over said operating temperature range. 10. An electronic circuit, comprising: a crystal having a first terminal and a second terminal; a crystal amplifier, comprising: an amplifier having an input coupled to said first terminal of said crystal and having an output coupled to said second terminal of said crystal; and a current source that provides a core bias current to said amplifier; and a first tune capacitor coupled between said second terminal of said crystal and a reference node and having a first capacitance, and a second tune capacitor coupled between said first terminal of said crystal and said reference node and having a second capacitance, wherein said first capacitance is greater than said second capacitance by a capacitance offset that has been determined to minimize frequency shift over an operating temperature range of said crystal amplifier; wherein said capacitance offset is maintained during operation of said crystal amplifier regardless of any change in temperature throughout said operating temperature range of said crystal amplifier. 11. The electronic circuit of claim 10 , wherein: said first tune capacitor is adjustable and has and adjust input; wherein said second tune capacitor is adjustable and has an adjust input; and further comprising a controller coupled to said adjust input of each of said first and second tune capacitors. 12. The electronic circuit of claim 11 , wherein each of said first and second tune capacitors comprises a plurality of capacitors and a corresponding plurality of switches, and wherein said controller controls said plurality of switches for selecting from among said plurality of capacitors. 13. A method of driving a crystal to oscillate at a resonant frequency, comprising: providing an amplifier input node and an amplifier output node for coupling across the crystal; providing an amplifier having an input coupled to the amplifier input node and having an output coupled to the amplifier output node; providing a core bias current to drive the amplifier; providing a first tune capacitor coupled between the amplifier output node and a reference node and having a first capacitance; providing a second tune capacitor coupled between the amplifier input node and the reference node and having a second capacitance; setting the first capacitance greater than the second capacitance by a capacitance offset that has been determined to minimize frequency shift over an operating temperature range of the crystal; and maintaining the capacitance offset during operation regardless of any change in temperature throughout the operating temperature range during operation. 14. The method of claim 13 , wherein said setting the first capacitance greater than the second capacitance comprises setting the first and second capacitances to have a combined capacitance that achieves an oscillating signal having a target frequency. 15. The method of claim 13 , wherein: said providing a first tune capacitor comprises providing a first adjustable tune capacitor; wherein said providing a second tune capacitor comprises providing a second adjustable tune capacitor; and wherein said setting the first capacitance greater than the second capacitance comprises adjusting the first and second capacitances with the capacitance offset and to have a combined capacitance that achieves an oscillating signal having a target frequency. 16. The method of claim 15 , further comprising storing an offset value indicative of the capacitance offset. 17. The method of claim 15 , wherein said providing a first adjustable tune capacitor and said providing a second adjustable tune capacitor each compris