Spur mitigation in a heterodyne upconversion system

What is claimed is: 1. A mixing system capable of upconverting an input signal of around 3 GHz to a desired output frequency in the n258 band within acceptable EESS band interference limits, the mixing system comprising: a programmable local oscillator (LO) signal generator for producing an LO signal having a selected LO frequency; a dual-mode upconversion circuit that is dynamically switchable between a low-side LO injection mode and a high-side LO injection mode; and a controller configured to dynamically program the LO signal generator and the dual-mode upconversion circuit LO injection mode based on a desired upconversion output frequency within the n258 band wherein the LO frequency and the LO injection mode are specifically configured such that LO leakage from combining the LO signal and the input signal falls outside of the EESS band. 2. A mixing system according to claim 1 , wherein the controller is configured to use the low-side LO injection mode when the desired upconversion output frequency is below a predetermined frequency and to use the high-side LO injection mode when the desired upconversion output frequency is above the predetermined frequency. 3. A mixing system according to claim 2 , wherein the mixing system supports a range of upconversion output frequencies, and wherein the predetermined frequency is substantially at the middle of the range of upconversion output frequencies. 4. A mixing system according to claim 2 , wherein the predetermined frequency is a predetermined intermediate frequency (IF). 5. A mixing system according to claim 1 , further comprising a tangible, non-transitory computer readable medium in which is stored a table mapping each of a number of output frequencies to a corresponding LO frequency and LO injection mode, and wherein the controller is configured to obtain from the table a desired LO frequency and LO injection mode based on the desired upconversion output frequency and dynamically program the LO signal generator and the dual-mode upconversion circuit using the desired LO frequency and LO injection mode. 6. A mixing system according to claim 1 , further comprising: a transmit circuit coupled to the dual-mode upconversion circuit for producing an upconverted transmit signal. 7. A mixing system according to claim 1 wherein the LO signal generator comprises: a programmable synthesizer. 8. A mixing system according to claim 1 wherein the LO signal generator comprises: a switchable LO circuit comprising a low-side LO generator circuit configured to generate the LO signal for a predetermined low-side frequency range, a high-side LO generator circuit configured to generate the LO signal for a predetermined high-side frequency range, and switching circuitry configured to switch between the low-side LO generator circuit and the high-side LO generator circuit based on the desired upconversion output frequency. 9. A mixing system according to claim 8 , wherein the low-side LO generator circuit is configured to generate the LO signal for a frequency range of 18-24 GHz, and wherein the high-side LO generator circuit is configured to generate the LO signal for a frequency range of 27-33 GHz. 10. A mixing system according to claim 1 , wherein the dual-mode upconversion circuit comprises: an I-channel mixer circuit; and a Q-channel mixer circuit, wherein the input signal is provided to an I-channel mixer via a −45 degree phase shifter and is provided to a Q-channel mixer via a +45 degree phase shifter, and wherein the LO signal is provided to the I-channel mixer via a programmable 180-degree hybrid and a +45 degree phase shifter and is provided to the Q-channel mixer via a programmable 180-degree hybrid and a −45 degree phase shifter, such that the 180-degree hybrids are controllable to dynamically select low-side LO injection or high-side LO injection. 11. A mixing system according to claim 10 , further comprising: a transmit circuit coupled to the dual-mode upconversion circuit for producing an upconverted transmit signal. 12. A mixing system according to claim 1 , further comprising: a dual-mode downconversion circuit that is dynamically switchable between a low-side LO injection mode and a high-side LO injection mode, wherein the controller is configured to dynamically switch the downconversion circuit between the low-side LO injection mode and the high-side LO injection mode based on a downconversion input frequency. 13. A mixing system according to claim 12 , further comprising: a switch configured to selectively switch the LO signal between the dual-mode upconversion circuit and the dual-mode downconversion circuit, wherein the controller is configured to selectively switch the LO signal between the dual-mode upconversion circuit and the dual-mode downconversion circuit based on a mixing mode. 14. A mixing system according to claim 12 , further comprising: a transceiver including a transmit circuit coupled to the dual-mode upconversion circuit for producing an upconverted transmit signal and a receive circuit coupled to the dual-mode downconversion circuit for producing a downconverted receive signal, wherein the controller is configured to selectively switch the LO signal between the dual-mode upconversion circuit and the dual-mode downconversion circuit based on whether the transceiver is in a transmitting mode or a receiving mode. 15. A dual mode mixer for converting between an n258 band signal and an intermediate frequency (IF) signal of around 3 GHz within acceptable EESS band interference limits, the dual mode mixer comprising: a programmable local oscillator (LO) signal generator for producing an LO signal having a selected LO frequency; a dual-mode mixer circuit that is dynamically switchable between a low-side LO injection mode and a high-side LO injection mode to convert between the n258 band signal and the IF signal based on the LO signal; and a controller configured to dynamically program the LO signal generator and the dual-mode mixer circuit LO injection mode based on the n258 band signal wherein the LO frequency and the LO injection mode are specifically configured such that LO leakage from the dual-mode mixer circuit falls outside of the EESS band. 16. A dual-mode mixer according to claim 15 , comprising: an I-channel mixer circuit; and a Q-channel mixer circuit, wherein the input signal is provided to an I-channel mixer via a −45 degree phase shifter and is provided to a Q-channel mixer via a +45 degree phase shifter, and wherein the LO signal is provided to the I-channel mixer via a programmable 180-degree hybrid and a +45 degree phase shifter and is provided to the Q-channel mixer via a programmable 180-degree hybrid and a −45 degree phase shifter, such that the 180-degree hybrids are controllable to dynamically select low-side LO injection or high-side LO injection. 17. A dual-mode mixer according to claim 15 , wherein the dual-mode mixer circuit is an upconverter circuit. 18. A dual-mode mixer according to claim 15 , wherein the dual-mode mixer circuit is a downconverter circuit. 19. A method for converting between an n258 band signal and an intermediate frequency (IF) signal of around 3 GHz within acceptable EESS band interference limits, the method comprising: programming a programmable local oscillator (LO) signal generator to produce an LO signal having a selected LO frequency; and programming a dual-mode mixer circuit that is dynamically switchable between a low-side LO injection mode and a high-side LO injection mode to convert between the n258 ba