Multi-stage LNA with reduced mutual coupling

We claim: 1. An apparatus comprising: at least two variable gain amplifier stages, each variable gain amplifier stage configured to accept an input signal and to provide a load driving signal; a tunable bandpass filter connected as a load to each variable gain amplifier stage, wherein each tunable bandpass filter includes: a resonant tank, each resonant tank including an inductor, wherein each inductor of each resonant tank is oriented in orthogonal relation with respect to each respective longitudinal axis of each next inductor, the orthogonal relation of the respective longitudinal axes configured to reduce mutual coupling between the tunable bandpass filters, a cross-coupled transistor pair, and at least one cross-coupled compensation transistor pair biased in a subthreshold region configured to add a transconductance component as a function of the respective load driving signal for the respective tunable bandpass filter; and, a controller circuit configured to tune each tunable bandpass filter. 2. The apparatus of claim 1 , wherein each inductor of each resonant tank is located on a same plane. 3. The apparatus of claim 1 , wherein each inductor is formed in a figure-8 type pattern, the longitudinal axes defining respective lengths of each inductor. 4. The apparatus of claim 1 , wherein each tunable bandpass filter includes a capacitor bank, and the controller circuit is configured to adjust each capacitor bank to alter the frequency response of each tunable bandpass filter. 5. The apparatus of claim 1 , wherein the controller circuit is configured to induce an oscillation in each tunable bandpass filter, to measure the resonant frequency of the oscillation, and to adjust the resonant frequency of each tunable bandpass filter. 6. The apparatus of claim 1 , wherein each variable gain amplifier stage is a transconductance amplifier stage having a plurality of parallel connected transconductance cells. 7. The apparatus of claim 1 , wherein each at least one cross-coupled compensation transistor pair comprises a plurality of parallel-connected cross-coupled compensation transistor pairs. 8. The apparatus of claim 1 , including a first low noise amplifier stage that includes a first variable gain amplifier stage of the at least two variable gain amplifier stages and a first tunable bandpass filter of the tunable bandpass filters, and including a second low noise amplifier stage that includes a second variable gain amplifier stage of the at least two variable gain amplifier stages and a second tunable bandpass filter of the tunable bandpass filters wherein the first low noise amplifier stage is configured to be tuned to a first frequency and the second low noise amplifier stage is configured to be tuned to a second frequency and wherein the second low noise amplifier stage is connected serially with the first low noise amplifier stage. 9. The apparatus of claim 8 , wherein the first frequency and second frequency are selected in accordance with a desired channel frequency. 10. A method comprising: adjusting the gain of at least two variable gain amplifier stages; adjusting a resonant frequency and a quality factor (Q) of at least two tunable bandpass filters respectively connected as respective loads to the at least two variable gain amplifier stages, wherein each tunable bandpass filter of the at least two tunable bandpass filters includes a cross-coupled transistor pair, at least one cross-coupled compensation transistor pair, and a resonant tank, each resonant tank including an inductor, wherein each inductor of each resonant tank is oriented in orthogonal relation with respect to each respective longitudinal axis of each next inductor, the orthogonal relation of the respective longitudinal axes configured to reduce mutual coupling between the at least two tunable bandpass filters; and, biasing the respective at least one cross-coupled compensation transistor pair in a subthreshold region. 11. The method of claim 10 , further comprising: inducing an oscillation in each tunable bandpass filter; measuring a resonant frequency of the respective oscillation; and, adjusting a respective resonant frequency of each tunable bandpass filter. 12. The method of claim 10 , further comprising adjusting the Q in each tunable bandpass filter to obtain a desired overall bandwidth and adjacent channel rejection ratio. 13. A method comprising: adjusting, to a first frequency, a resonant frequency of a first low noise amplifier stage having a first variable gain amplifier stage and a first tunable bandpass filter; adjusting, to a second frequency offset from the first frequency, a resonant frequency of a second low noise amplifier stage having a second variable gain amplifier stage and a second tunable bandpass filter; biasing cross-coupled compensation transistor pairs in each of the first tunable bandpass filter and second tunable bandpass filter in a sub-threshold region; and orienting the first and second tunable bandpass filters to reduce mutual coupling by providing a resonant tank within each of the first and second tunable bandpass filters with an inductor, wherein each inductor of each resonant tank is oriented in orthogonal relation with respect to each respective longitudinal axis of each next inductor, the orthogonal relation of the respective longitudinal axes configured to reduce mutual coupling between the first and second tunable bandpass filters. 14. The method of claim 13 , wherein the first frequency and second frequency are selected in accordance with a desired channel frequency. 15. The method of claim 13 , further comprising adjusting a quality factor (Q) of the first and second tunable bandpass filters of the first and second low noise amplifier stages to obtain a desired overall bandwidth and adjacent channel rejection ratio. 16. The method of claim 13 , wherein adjusting the respective resonant frequencies of the first and second low noise amplifier stages respectively comprises: inducing an oscillation in the respective tunable bandpass filter; measuring the resonant frequency of the respective oscillation; and, adjusting the resonant frequency of the respective tunable bandpass filter.