Phased array antenna panel having reduced passive loss of received signals

The invention claimed is: 1. A phased array antenna panel, comprising: a first radio frequency (RF) front end chip between a first plurality of antennas, wherein said first RF front end chip is configured to: receive first input signals from said first plurality of antennas; and produce a first phase-shifted output signal based on a first phase shift of said first input signals; a second RF front end chip between a second plurality of antennas, wherein said second RF front end chip is configured to: receive second input signals from said second plurality of antennas; and produce a second phase-shifted output signal based on a second phase shift of said second input signals; and a combiner RF chip comprising: an input buffer configured to: receive the first phase-shifted output signal from said first RF front end chip; and receive the second phase-shifted output signal from said second RF front end chip; a power combiner configured to combine the first phase-shifted output signal with the second phase-shifted output signal; and an output buffer configured to generate a buffered power combined output signal from the first phase-shifted output signal and the second phase-shifted output signal. 2. The phased array antenna panel of claim 1 , wherein said combiner RF chip comprises a lumped-element power combiner. 3. The phased array antenna panel of claim 2 , wherein said lumped-element power combiner comprises at least one of an on-chip capacitor or an inductor. 4. The phased array antenna panel of claim 1 , wherein said first phase-shifted output signal and said second phase-shifted output signal are fed into respective input buffers in said combiner RF chip. 5. The phased array antenna panel of claim 1 , wherein said combiner RF chip is substantially centered between said first RF front end chip and said second RF front end chip. 6. The phased array antenna panel of claim 1 , further comprising a master chip configured to: provide a first phase shift signal to said first plurality of antennas via said first RF front end chip; and provide a second phase shift signal to said second plurality of antennas via said second RF front end chip. 7. The phased array antenna panel of claim 1 , further comprising a master chip configured to: drive in parallel a plurality of control and data buses coupled to said first plurality of antennas and said second plurality of antennas; provide a first amplitude control signal to said first plurality of antennas via said first RF front end chip; and provide a second amplitude control signal to said second plurality of antennas via said second RF front end chip. 8. The phased array antenna panel of claim 1 , wherein said power combiner is a lumped-element power combiner. 9. The phased array antenna panel of claim 1 , wherein said power combiner is a microstrip power combiner. 10. A phased array antenna panel, comprising: a master chip configured to drive a plurality of control and data buses coupled to a first plurality of antennas and a second plurality of antennas; a first radio frequency (RF) front end chip between said first plurality of antennas, wherein said first RF front end chip is configured to: receive first input signals from said first plurality of antennas; and produce a first phase-shifted output signal based on a first phase shift of said first input signals; a second RF front end chip between said second plurality of antennas, wherein said second RF front end chip is configured to: receive second input signals from said second plurality of antennas; and produce a second phase-shifted output signal based on a second phase shift of said second input signals; a power combiner on a substrate of said phased array antenna panel, wherein said power combiner comprises input buffers coupled to the first phase-shifted output signal and the second phase-shifted output signal, an impedance of the input buffers is matched to an impedance of a power combined output line, said input buffers are configured to receive said first phase-shifted output signal and said second phase-shifted output signal based on the impedance matching, and said power combiner is configured to output a power combined output signal, via the power combined output line, based on said first phase-shifted output signal and said second phase-shifted output signal; and a combiner RF chip configured to receive said power combined output signal via the power combined output line. 11. The phased array antenna panel of claim 10 , wherein said combiner RF chip is further configured to produce a buffered power combined output signal based on said power combined output signal. 12. The phased array antenna panel of claim 10 , wherein each antenna of said first plurality of antennas and said second plurality of antennas comprises vertically polarized probe and horizontally polarized probe. 13. The phased array antenna panel of claim 10 , wherein said combiner RF chip is substantially centered between said first RF front end chip and said second RF front end chip. 14. The phased array antenna panel of claim 10 , wherein said master chip is further configured to: provide a first phase shift signal to said first plurality of antennas via said first RF front end chip; and provide a second phase shift signal to said second plurality of antennas via said second RF front end chip. 15. The phased array antenna panel of claim 10 , wherein said master chip is further configured to: provide a first amplitude control signal to said first plurality of antennas via said first RF front end chip; and provide a second amplitude control signal to said second plurality of antennas via said second RF front end chip. 16. A phased array antenna panel, comprising: a master chip configured to drive a plurality of control and data buses coupled to a first plurality of antennas and a second plurality of antennas; a first radio frequency (RF) front end chip between said first plurality of antennas, wherein said first RF front end chip is configured to: receive first input signals from said first plurality of antennas, and produce a first amplified output signal based on a first amplification of said first input signals; a second RF front end chip between said second plurality of antennas, wherein said second RF front end chip is configured to: receive second input signals from said second plurality of antennas; and produce a second amplified output signal based on a second amplification of said second input signals; a combiner RF chip comprises: an input buffer configured to: receive the first amplified output signal from said first RF front end chip; and receive the second amplified output signal from said second RF front end chip; and a power combiner configured to combine the first amplified output signal with the second amplified output signal; and an output buffer configured to generate a buffered power combined output signal from the first amplified output signal and the second amplified output signal.