ESA phase shifter topology

What is claimed is: 1. A phase shifter topology circuit comprising: an I/Q generator configured to receive an input signal, and generate an in-phase (I) signal and a quadrature-phase (Q) signal based on the input signal; a first variable amplitude amplifier arranged to receive the I signal from the I/Q generator, and configured to adjust the phase of and amplify the I signal to provide an inphase I signal and an outphase I signal 180° out of phase with the inphase I signal; a second variable amplitude amplifier arranged to receive the Q signal from the I/Q generator, and configured to adjust the phase of and amplify the Q signal to provide an inphase Q signal and an outphase Q signal 180° out of phase with the inphase Q signal; and a phase shifter component arranged to selectively receive the outphase I signal or the inphase I signal from the first variable amplitude amplifier and to selectively receive the outphase Q signal or the inphase Q signal from the second variable amplitude amplifier, and configured to control the gain of the received outphase or inphase I signal and the received outphase or inphase Q signal to provide a composite output signal with a desired phase shift between 0° and 360°. 2. The phase shifter topology circuit of claim 1 , where the phase shifter component comprises: a first gain portion comprising only two transistor elements arranged to amplify the received outphase or inphase I signal; and a second gain portion comprising only two transistor elements arranged to amplify the received outphase or inphase Q signal. 3. The phase shifter topology circuit of claim 2 , wherein each of the transistor elements of the first and second gain portions comprises three transistors configured to be a super transistor. 4. The phase shifter topology circuit of claim 1 , wherein the first variable amplitude amplifier has a first gain portion configured to amplify the I signal, and the second variable amplitude amplifier has a second gain portion configured to amplify the Q signal. 5. The phase shifter topology circuit of claim 4 , wherein the first gain portion comprises two pairs of transistors cross coupled with each other, and the second gain portion comprises two pairs of transistors cross coupled with each other. 6. The phase shifter topology circuit of claim 5 , wherein each of the transistors of the pairs of transistors of the first and second gain portions comprises three transistors configured to be a super transistor. 7. The phase shifter topology circuit of claim 1 , further comprising a control circuit configured to provide control signals to the first and second variable amplitude amplifiers and the phase shifter component to control the amplification provided by the first and second variable amplitude amplifiers and the phase shifter component. 8. The phase shifter topology circuit of claim 5 , wherein the first variable amplitude amplifier has a first control portion configured to provide current to the transistors of the first gain portion to control the amplification provided by the first gain portion, and the second variable amplitude amplifier has a second control portion configured to provide current to the transistors of the second gain portion to control the amplification provided by the second gain portion. 9. The phase shifter topology circuit of claim 2 , wherein the phase shifter component has a first control portion configured to provide current to the transistors of the first gain portion to control the amplification provided by the first gain portion, and a second control portion configured to provide current to the transistors of the second gain portion to control the amplification provided by the second gain portion. 10. A phase shifter component, comprising: inputs arranged to selectively receive an inphase component of an in-phase (I) signal or an outphase I signal 180° out of phase with the inphase I signal, and to selectively receive an inphase component of a quadrature-phase (Q) signal or an outphase Q signal 180° out of phase with the inphase Q signal; a first gain portion comprising only two transistor elements arranged to amplify the received outphase or inphase I signal; and a second gain portion comprising only two transistor elements arranged to amplify the received outphase or inphase Q signal, and the first and second gain portions configured to control the gain of the received outphase or inphase I signal and the received outphase or inphase Q signal, respectively, to provide a composite output signal with a desired phase shift between 0° and 360°. 11. The phase shifter component of claim 10 , wherein each of the transistor elements of the first and second gain portions comprises three transistors configured to be a super transistor. 12. The phase shifter component of claim 10 , further comprising: a first control portion configured to provide current to the transistors of the first gain portion to control the amplification provided by the first gain portion, and a second control portion configured to provide current to the transistors of the second gain portion to control the amplification provided by the second gain portion. 13. An electronically scanned antenna array comprising: a plurality of antenna elements configured to transmit a beam comprising signals emitted by the antenna elements; and a plurality of phase shifter topology circuits configured to adjust the amplitudes of signals provided to the antenna elements for emission, wherein each phase shifter topology circuit comprises: an I/Q generator configured to receive an input signal, and generate an in-phase (I) signal and a quadrature-phase (Q) signal based on the input signal; a first variable amplitude amplifier arranged to receive the I signal from the I/Q generator, and configured to adjust the phase of and amplify the I signal to provide an inphase I signal and an outphase I signal 180° out of phase with the inphase I signal; a second variable amplitude amplifier arranged to receive the Q signal from the I/Q generator, and configured to adjust the phase of and amplify the Q signal to provide an inphase Q signal and an outphase Q signal 180° out of phase with the inphase Q signal; and a phase shifter component arranged to selectively receive the outphase I signal or the inphase I signal from the first variable amplitude amplifier and to selectively receive the outphase Q signal or the inphase Q signal from the second variable amplitude amplifier, and configured to control the gain of the received outphase or inphase I signal and the received outphase or inphase Q signal to provide a composite output signal with a desired phase shift between 0° and 360°. 14. The electronically scanned antenna array of claim 13 , where the phase shifter component comprises: a first gain portion comprising only two transistor elements arranged to amplify the received outphase or inphase I signal; and a second gain portion comprising only two transistor elements arranged to amplify the received outphase or inphase Q signal. 15. The electronically scanned antenna array of claim 14 , wherein each of the transistor elements of the first and second gain portions comprises three transistors configured to be a super transistor. 16. The electronically scanned antenna array of claim 13 , wherein the first variable amplitude amplifier has a first gain portion configured to amplify the I signal, and the second variable amplitude amplifier has a second gain portion configured to amplify the Q signal. 17. The electronically scanned antenna array of claim 16 , wherein the