Using a multi-tone signal to tune a multi-stage low-noise amplifier

I claim: 1. A method, comprising: reducing a quality factor of a first tunable bandpass filter for a first calibration period; receiving a first wideband test signal centered at a desired center frequency of a second tunable bandpass filter; during the first calibration period, estimating a frequency response of the second tunable bandpass filter to the first wideband test signal using a Fast Fourier Transform (FFT) signal processor; calibrating at least a resonant frequency or a quality factor of the second tunable bandpass filter based at least in part on a portion of the estimated frequency response of the second tunable bandpass filter obtained from the FFT signal processor; following the first calibration period, reducing the quality factor of the second tunable bandpass filter for a second calibration period; receiving a second wideband test signal centered at a desired center frequency of the first tunable bandpass filter; during the second calibration period, estimating a frequency response of the first tunable bandpass filter to the second wideband test signal using the FFT signal processor; and calibrating at least a resonant frequency or the quality factor of the first tunable bandpass filter based at least in part on a portion of the estimated frequency response of the first tunable bandpass filter obtained from the FFT signal processor. 2. The method of claim 1 , wherein a first low-noise amplifier (LNA) stage comprises the first tunable bandpass filter and a second LNA stage comprises the second tunable bandpass filter. 3. The method of claim 2 , wherein an output of the first LNA stage is connected to an input of the second LNA stage. 4. The method of claim 2 , wherein an output of the second LNA stage is connected to an input of the first LNA stage. 5. The method of claim 1 , wherein the first and second wideband test signals are identical apart from being centered at different desired center frequencies, the desired center frequency of the first tunable bandpass filter being different from the desired center frequency of the second tunable bandpass filter. 6. The method of claim 1 , wherein at least the first wideband test signal is an Orthogonal Frequency Division Multiplexing (OFDM) training sequence. 7. The method of claim 1 , wherein at least the first wideband test signal comprises a multi-tone signal having signal components at multiple distinct tones within the same signal. 8. The method of claim 1 , further comprising: prior to determining the estimated frequency response of the first second bandpass filter, calibrating a receiver stage, wherein an input of the receiver stage is connected to an output of the second tunable bandpass filter and an output of the receiver stage is connected to an input of the FFT signal processor. 9. The method of claim 1 , further comprising: prior to determining the estimated frequency response of the second tunable bandpass filter, performing a coarse calibration of the second tunable bandpass filter. 10. The method of claim 9 , wherein performing the coarse calibration of the second tunable bandpass filter comprises: inducing an oscillation in the second tunable bandpass filter; measuring the resonant frequency of the second tunable bandpass filter; and adjusting the resonant frequency of the second tunable bandpass filter toward a desired center frequency prior to receiving the first wideband test signal centered at the desired center frequency of the second tunable bandpass filter. 11. A method, comprising: permitting focused estimation of a frequency response of a first tunable bandpass filter by reducing a quality factor of a second tunable bandpass filter; receiving a wideband test signal, wherein the wideband test signal is centered at a desired center frequency of the first tunable bandpass filter; generating a digital output sequence at a receiver stage from a filtered version of the wideband test signal provided to the receiver stage from a cascade of at the first and the second tunable bandpass filters; analyzing the digital output sequence of the receiver stage by applying a Fast Fourier Transform (FFT) algorithm to the digital output sequence to estimate the frequency response of the first tunable bandpass filter; calibrating the first tunable bandpass filter by adjusting at least one of a quality factor and a resonant frequency of the first tunable bandpass filter based at least in part on the estimated frequency response of the first tunable bandpass filter at the desired center frequency of the first tunable bandpass filter and one or more other frequencies defining a desired bandwidth of the first tunable bandpass filter; and following calibration of the first tunable bandpass filter, receiving a modulated radio frequency signal having a variable phase component. 12. The method of claim 11 , wherein a first low-noise amplifier (LNA) stage comprises the first tunable bandpass filter and a second LNA stage comprises the second tunable bandpass filter, and wherein calibrating the first tunable bandpass filter comprises adjusting a gain of the first LNA stage. 13. The method of claim 11 , wherein the one or more frequencies defining a desired bandwidth of the first tunable bandpass filter comprise a desired lower cutoff frequency and a desired upper frequency of the first tunable bandpass filter. 14. The method of claim 11 , further comprising: prior to receiving the modulated radio frequency signal having the variable phase component: permitting focused estimation of a frequency response of the second tunable bandpass filter by reducing the quality factor of the first tunable bandpass filter; receiving a second wideband test signal, wherein the second wideband test signal is centered at a desired center frequency of the second tunable bandpass filter; generating a second digital bit sequence at the receiver stage from a filtered version of the second wideband test signal provided to the receiver stage from the cascade of at least the first and second tunable bandpass filters; analyzing the second digital bit sequence of the receiver stage by applying the FFT algorithm to the digital bit sequence to estimate the frequency response of the second tunable bandpass filter; and calibrating the second tunable bandpass filter based at least in part on the estimated frequency response of the second tunable bandpass filter at the desired center frequency of the second tunable bandpass filter and one or more other frequencies defining a desired bandwidth of the second tunable bandpass filter. 15. The method of claim 11 , further comprising: further permitting focused estimation of the frequency response of the first tunable bandpass filter by calibrating the receiver stage prior to determining the estimated frequency response of the first tunable bandpass filter. 16. A method implemented by a polar transceiver, comprising: transmitting, during a testing mode, a wideband test signal centered at a desired center frequency of a tunable bandpass filter of a low-noise amplifier (LNA) stage; amplifying the wideband test signal in at least the LNA stage to generate an amplified analog output signal; performing Fast Fourier Transform (FFT) analysis on a digital output sequence derived from the amplified analog output signal to provide an estimated frequency response of the LNA stage, the estimated frequency response including signal magnitudes at multiple frequencies of the wideband test signal; responsively calibrating the tunable bandpass filter based at least in part on the estimated frequency response of