Systems and methods for integration of injection-locked oscillators into transceiver arrays

What is claimed is: 1. An injection-locked oscillator distribution system, comprising: a master clock generator configured to generate a master clock signal; a transceiver circuit including a plurality of mixers; and an injection-locked oscillator distribution circuit including a plurality of injection-locked oscillators, each of the injection-locked oscillators configured to receive the master clock signal, each of the injection-locked oscillators configured to generate a reference clock signal based on the master clock signal, each of the injection-locked oscillators configured to provide the reference clock signal to one of the mixers, the injection-locked oscillator distribution circuit further configured generate output signals each indicative of an operating frequency of a corresponding one of the injection-locked oscillators, the injection-locked oscillator distribution circuit further including an injection-locked detector configured to receive the master clock signal and the output signals and to determine whether the injection-locked oscillators are in locked or unlocked states based on the master clock signal and the output signals. 2. The injection-locked oscillator distribution system of claim 1 further including an additional injection-locked oscillator distribution circuit including a plurality of additional injection-locked oscillators, each of the additional injection-locked oscillators configured to generate the reference clock signal and provide the reference clock signal to one of the mixers. 3. The injection-locked oscillator distribution system of claim 1 wherein the master clock generator includes a master phase-locked loop and a multi-phase clock pulse-generator, the master phase-locked loop configured to receive a reference frequency signal as an input and generate an output signal having a phase that is clocked to the phase of the reference frequency signal, the multi-phase clock pulse-generator configured to receive the output signal from the master phase-locked loop, generate a master signal, and provide the master signal to the injection-locked oscillator distribution circuit. 4. The injection-locked oscillator distribution system of claim 1 wherein each of the injection-locked oscillators is further configured to generate the reference clock signal having a higher frequency than the master clock signal and the injection-locked oscillator distribution circuit is further configured to generate the output signal of the corresponding one of the injection-locked oscillators via down-converting the reference clock signal of the corresponding one of injection-locked oscillators to a frequency of the master clock signal. 5. The injection-locked oscillator distribution system of claim 4 wherein the injection-locked oscillator distribution circuit further includes, for each of the injection-locked oscillators, a mixer configured to generate the output signal for the corresponding one of the injection-locked oscillators. 6. The injection-locked oscillator distribution system of claim 4 wherein the injection-locked oscillator distribution circuit further includes, for each of the injection-locked oscillators, divider circuitry configured to generate the output signal for the corresponding one of the injection-locked oscillators. 7. The injection-locked oscillator distribution system of claim 1 wherein the injection-locked detector includes a mixer configured to mix the output signal of at least one of the injection-locked oscillators with the master clock signal to generate an intermediate mixed signal, the injection-locked detector further configured to determine whether the at least one of the injection-locked oscillator is in the locked state or in the unlocked state based on the intermediate mixed signal. 8. The injection-locked oscillator distribution system of claim 7 wherein the injection-locked detector includes selection logic for providing a selected one of the output signals to the mixer at a time. 9. A method of distributing a reference clock signal, comprising: generating, by a master clock generator, a master clock signal; receiving, at an injection-locked oscillator distribution circuit, the master clock signal, the injection-locked oscillator distribution circuit including a plurality of injection-locked oscillators; generating, at each of the injection-locked oscillators, a reference clock signal based on the master clock signal; providing the reference clock signal from each of the injection-locked oscillators to a plurality of mixers; generating, at the injection-locked oscillator distribution circuit, output signals each indicative of an operating frequency of a corresponding one of the injection-locked oscillators; and determining, at an injection-locked detector, whether the injection-locked oscillators are in locked or unlocked states based on the master clock signal and the output signals. 10. The method of claim 9 further comprising: generating, at each of each of a plurality of additional injection-locked oscillators, the reference clock signal; and providing the reference clock signal from each of the additional injection-locked oscillators to one of the mixers. 11. The method of claim 9 further comprising: generating, at a master phase-locked loop of the master clock generator, an output signal having a phase that is clocked to the phase of a reference frequency signal received as an input; and generating, at a multi-phase clock pulse-generator of the master clock generator, a master signal based on the output signal from the master phase-locked loop and providing the master signal to the injection-locked oscillator distribution circuit. 12. The method of claim 9 further comprising: generating, at the each of the injection-locked oscillators, the reference clock signal having a higher frequency than the master clock signal; and generating, at the injection-locked oscillator distribution circuit, the output signal of the corresponding one of the injection-locked oscillators via down-converting the reference clock signal of the corresponding one of the injection-locked oscillators to a frequency of the master clock signal. 13. The method of claim 12 further comprising, for each of the injection-locked oscillators, generating the output signal for the corresponding one of the injection-locked oscillators at a mixer of the injection-locked oscillator distribution circuit. 14. The method of claim 12 further comprising, for each of the injection-locked oscillators, generating the output signal for the corresponding one of the injection-locked oscillators at divider circuitry the injection-locked oscillator distribution circuit. 15. The method of claim 9 further comprising: mixing, at a mixer included in the injection-locked detector, the output signal of a first injection-locked oscillator of the injection-locked oscillators with the master clock signal to generate an intermediate mixed signal; and determining, at the injection-locked detector, whether the first injection-locked oscillator is in the locked state or in the unlocked state based on the intermediate mixed signal. 16. The method of claim 15 further comprising, with selection logic, selecting the output signal of the first injection locked oscillator for mixing with the master clock signal. 17. A mobile device, comprising: an antenna; a transceiver circuit operatively coupled to the antenna, the transceiver circuit including a plurality of mixers; a master clock generator configured to generate a master clock signal; and an injection-locked oscill