Oscillator scheme capable of reducing far-out phase noise and closed-in phase noise

What is claimed is: 1. An oscillator apparatus, comprising: an oscillator core circuit, comprising: an inverting transconductance amplifier; at least one first capacitor, connected between an input of the inverting transconductance amplifier and a ground level; at least one second capacitor, connected between an output of the inverting transconductance amplifier and the ground level; and a resonator, having a first port connected to the input of the inverting transconductance amplifier and a second port connected to the output of the inverting transconductance amplifier, the first port of the resonator being decoupled from the second port of the resonator; a DC coupling circuit, having one end connected to the input of the inverting transconductance amplifier and the first port and having another end connected to a driver; and the driver, having an input DC coupled to the first port via the DC coupling circuit. 2. The oscillator apparatus of claim 1 , wherein a DC voltage bias level at the first port is controlled not based on a DC voltage bias level at the second port. 3. An oscillator apparatus, comprising: an oscillator core circuit, comprising: an inverting transconductance amplifier; at least one first capacitor, connected between an input of the inverting transconductance amplifier and a ground level; at least one second capacitor, connected between an output of the inverting transconductance amplifier and the ground level; and a resonator, having a first port connected to the input of the inverting transconductance amplifier and a second port connected to the output of the inverting transconductance amplifier, the first port of the resonator being decoupled from the second port of the resonator; and a bias circuit, connected to the first port, configured to provide a common mode voltage level for a voltage signal at the first port. 4. The oscillator apparatus of claim 1 , wherein the driver comprises at least one of a squarer, an inverter buffer, and a voltage gain buffer. 5. The oscillator apparatus of claim 3 , wherein the bias circuit comprises: an inverter, biased and controlled by a specific current of a current source, an output of the inverter being connected to an input of the inverter; and a resistor, connected between the first port of the resonator and the input of the inverter, wherein the driver is further biased by the specific current of the current source. 6. The oscillator apparatus of claim 1 , wherein the bias circuit comprises: a resistor, having one end connected to an input of the driver and another end connected to an output of the driver. 7. The oscillator apparatus of claim 1 , wherein: the at least one first capacitor comprises a plurality of first capacitors connected in parallel and selectively coupled to the first port of the resonator via a plurality of first switches respectively; and the at least one second capacitor comprises a plurality of second capacitors connected in parallel and selectively coupled to the second port of the resonator via a plurality of second switches respectively. 8. The oscillator apparatus of claim 1 , wherein a capacitance of the at least one first capacitor is smaller than a capacitance of the at least one second capacitor. 9. An oscillator apparatus, comprising: an oscillator core circuit, comprising: an inverting transconductance amplifier; at least one first capacitor, connected between an input of the inverting transconductance amplifier and a ground level; at least one second capacitor, connected between an output of the inverting transconductance amplifier and the ground level; and a resonator, having a first port connected to the input of the inverting transconductance amplifier and a second port connected to the output of the inverting transconductance amplifier, the first port of the resonator being decoupled from the second port of the resonator, wherein a capacitance of the at least one first capacitor is smaller than a capacitance of the at least one second capacitor, and wherein an amplitude of a voltage signal at the first port of the resonator is larger than an amplitude of a voltage signal at the second port of the resonator. 10. The oscillator apparatus of claim 8 , wherein the at least one first capacitor is a linear capacitor, and the at least one second capacitor is a high density capacitor.