Low-power, low-noise millimeter wavelength frequency synthesizer

What is claimed is: 1. A system that implements a frequency synthesizer, comprising: an intermediate-frequency (IF) synthesizer that generates an IF signal based on a reference signal; a sub-sampling phase-locked loop (SSPLL) that generates a high-frequency output signal based on an input signal; a switch that selects either the reference signal or the IF signal to be the input signal to the SSPLL, wherein when the reference signal is the input signal to the SSPLL, the frequency synthesizer operates in a low-noise normal-operating mode in which the frequency synthesizer can become unlocked from a desired target frequency, and when the IF signal is the input signal to the SSPLL, the frequency synthesizer operates in a higher-noise, frequency-acquisition mode in which the frequency synthesizer automatically locks to the target frequency; and a sub-sampling lock detector (SSLD), which is configured to: determine whether the frequency synthesizer becomes unlocked from the target frequency during the normal-operating mode, and if so, to activate the switch to move the frequency synthesizer into the frequency-acquisition mode, and determine whether the frequency synthesizer becomes relocked to the target frequency during the frequency-acquisition mode, and if so, to activate the switch to move the frequency synthesizer into the normal-operating mode. 2. The system of claim 1 , wherein the SSLD is configured to determine a locking status of the frequency synthesizer by: sampling the SSPLL output using the IF signal to produce a detection signal; measuring a frequency of the detection signal; and determining the locking status of the frequency synthesizer based on the frequency of the detection signal. 3. The system of 2 , wherein the locking status can be one of the following: the SSPLL output signal is properly locked to a harmonic of the IF signal; the SSPLL output signal is improperly locked to a harmonic of the reference signal, which is not a harmonic of the IF signal; and the SSPLL output signal is not locked to any signal. 4. The system of claim 1 , wherein the SSLD is configured to operate with reference to the IF signal and thereby consumes less power than a comparable circuit that operates at a higher frequency. 5. The system of claim 1 , wherein the IF synthesizer comprises a phase-locked loop (PLL). 6. The system of claim 5 , wherein the PLL comprises: a forward path, which feeds the reference signal through a phase-frequency detector (PFD) to produce an error signal, wherein a charge pump converts the error signal into a voltage, which feeds through a loop filter and is used to tune a voltage-controlled oscillator to produce the IF signal; and a feedback path, which feeds the IF signal through a frequency divider to produce a feedback signal; wherein during operation, the PFD compares the reference signal against the feedback signal to produce the error signal. 7. The system of claim 1 , wherein the SSPLL comprises: a forward path, which feeds the IF signal through a sub-sampling phase detector (SSPD) to produce an error signal, wherein a charge pump converts the error signal into a voltage, which feeds through a loop filter and is used to tune a voltage-controlled oscillator to produce a high-frequency output signal; wherein during operation, the SSPD samples the reference signal using the high-frequency output signal to produce the error signal. 8. The system of claim 1 , wherein the frequency of the IF signal is sufficiently high to ensure that the SSPLL can only lock to one frequency (the target frequency) which is an integer multiple of the IF. 9. The system of claim 1 , wherein the SSLD uses a pseudo-digital state machine, which includes digital circuitry but is not driven by an external clock, to control activation of the switch. 10. The system of claim 1 , wherein the switch comprises a multiplexer. 11. A method for operating a frequency synthesizer, comprising: feeding a reference signal into an intermediate-frequency (IF) synthesizer, which generates an IF signal based on the reference signal; feeding the IF signal and the reference signal into a switch, which is configured to select either the reference signal or the IF signal to be an input signal to a sub-sampling phase-locked loop (SSPLL), which generates a high-frequency output signal based on the input signal; wherein when the reference signal is the input signal to the SSPLL, the frequency synthesizer operates in a low-noise normal-operating mode in which the frequency synthesizer can become unlocked from a desired target frequency; an wherein when the IF signal is the input signal to the SSPLL, the frequency synthesizer operates in a higher-noise, frequency-acquisition mode in which the frequency synthesizer automatically locks to the target frequency; feeding the IF signal and the high-frequency output signal into a sub-sampling lock detector (SSLD); and operating the SSLD, which involves, determining whether the frequency synthesizer becomes unlocked from the target frequency during the normal-operating mode, and if so, activating the switch to move the frequency synthesizer into the frequency-acquisition mode, and determining whether the frequency synthesizer becomes relocked to the target frequency during the frequency-acquisition mode, and if so, activating the switch to move the frequency synthesizer into the normal-operating mode. 12. The method of claim 11 , wherein while operating the SSLD, the method determines a locking status of the frequency synthesizer, which involves: sampling the SSPLL output using the IF signal to produce a detection signal; measuring a frequency of the detection signal; and determining the locking status of the frequency synthesizer based on the frequency of the detection signal. 13. The method of 12 , wherein the locking status can be one of the following: the SSPLL output signal is properly locked to a harmonic of the IF signal; the SSPLL output signal is improperly locked to a harmonic of the reference signal, which is not a harmonic of the IF signal; and the SSPLL output signal is not locked to any signal. 14. The method of claim 11 , wherein the SSLD operates with reference to the IF signal and thereby consumes less power than a comparable circuit that operates at a higher frequency. 15. The method of claim 11 , wherein the IF synthesizer comprises a phase-locked loop (PLL). 16. The method of claim 11 , wherein the SSPLL comprises: a forward path, which feeds the IF signal through a sub-sampling phase detector (SSPD) to produce an error signal, wherein a charge pump converts the error signal into a voltage, which feeds through a loop filter and is used to tune a voltage-controlled oscillator to produce the high-frequency output signal; wherein during operation, the SSPD samples the reference signal using the high-frequency output signal to produce the error signal. 17. The method of claim 11 , wherein operating the SSLD involves using a pseudo-digital state machine, which includes digital circuitry but is not driven by an external clock, to control activation of the switch. 18. An apparatus that includes a frequency synthesizer, comprising: an electronic system that uses a high-frequency output signal produced by the frequency synthesizer to control various operations performed by the electronic system; the frequency synthesizer, which is coupled to an electronic system, wherein the frequency synthesizer comprises: an intermediate-frequency (IF) synthesizer that generates an IF signal based on