Spectral stitching method to increase instantaneous bandwidth in vector signal analyzers

We claim: 1. An apparatus for processing a signal, the apparatus comprising: a first signal processing pathway configured to: receive a first component signal comprising a first frequency band of an input signal; and digitize the first component signal; a second signal processing pathway, phase-locked and time-synchronized with respect to the first signal processing pathway, the second signal processing pathway configured to: receive a second component signal comprising a second frequency band of the input signal, the second frequency band having a region of overlap with the first frequency band; and digitize the second component signal; wherein, when the second signal processing pathway is in a calibration mode, the second signal processing pathway is further configured to compute a complex calibration constant, wherein the complex calibration constant is computed based on a phase difference between a first digitized version of a calibration tone output of by the first signal processing pathway and a second digitized version of the calibration tone output by the second signal processing pathway, wherein the calibration tone is included within the region of overlap between the first frequency band and the second frequency band; and a memory configured to store the complex calibration constant. 2. The apparatus of claim 1 , wherein, when the second signal processing pathway is not in the calibration mode, the second signal processing pathway is further configured to: correct, via application of the stored complex calibration constant, phase mismatch between a digitized output of the first signal processing pathway and a digitized output of the second signal processing pathway, using the stored calibration constant. 3. The apparatus of claim 1 , wherein the complex calibration constant is computed further based on a ratio of a magnitude of the first digitized version of the calibration tone and a magnitude of the second digitized version of the calibration tone. 4. The apparatus of claim 1 , wherein the first signal processing pathway is further configured to: filter the first component signal; and wherein the second signal processing pathway is further configured to: filter the second component signal; wherein said filtering of the first and second component signals is configured to cause a sum of the first and second component signals to have a unity frequency response within the region of overlap. 5. The apparatus of claim 4 , wherein said filtering is performed by one or more half-band filters. 6. The apparatus of claim 1 , wherein said digitizing the first component signal comprises shifting the first component signal such that the first frequency band is at baseband, and said digitizing the second component signal comprises shifting the second component signal such that the second frequency band is at baseband; wherein the second signal processing pathway is further configured to: frequency-shift the digitized second component signal such that a frequency offset between the digitized first component signal and the digitized second component signal is the same as a frequency offset between the first frequency band of the input signal and the second frequency band of the input signal. 7. The apparatus of claim 6 , wherein the first signal processing pathway is further configured to: interpolate the first component signal, wherein said interpolating is performed after said digitizing the first component signal and before said frequency-shifting the digitized first component signal; wherein the second signal processing pathway is further configured to: interpolate the second component signal, wherein said interpolating is performed after said digitizing the second component signal and before said frequency-shifting the digitized second component signal. 8. An apparatus for processing a signal, the apparatus comprising: a first signal processing pathway that is phase-locked and time-synchronized with respect to a second signal processing pathway, the first signal processing pathway configured to: receive a first component signal comprising a first frequency band of an input signal, the first frequency band having a region of overlap with a second frequency band of the input signal; digitize the first component signal; compute a complex calibration constant, wherein the complex calibration constant is computed based on a phase difference between a first digitized version of a calibration tone output by the first signal processing pathway and a second digitized version of the calibration tone output by the second signal processing pathway when an input of the second signal processing pathway comprises the second frequency band, wherein the calibration tone is included within the region of overlap between the first frequency band and the second frequency band; and a memory configured to store the complex calibration constant. 9. The apparatus of claim 8 , wherein the first signal processing pathway is further configured to: correct, via application of the stored complex calibration constant, phase mismatch between a digitized output of the first signal processing pathway and a digitized output of the second signal processing pathway, using the stored calibration constant. 10. The apparatus of claim 8 , wherein the complex calibration constant is computed further based on a ratio of a magnitude of the first digitized version of the calibration tone and a magnitude of the second digitized version of the calibration tone. 11. The apparatus of claim 8 , wherein the first signal processing pathway is further configured to: filter the first component signal, wherein said filtering the first component signal is configured to cause a sum of the output of the first signal processing pathway and the output of the second signal processing pathway to have a unity frequency response within the region of overlap. 12. The apparatus of claim 11 , wherein said filtering is performed by one or more half-band filters. 13. The apparatus of claim 8 , wherein said digitizing the first component signal comprises shifting the first component signal such that the first frequency band is at baseband; wherein the first signal processing pathway is further configured to: frequency-shift the digitized first component signal such that a frequency offset between the output of the first signal processing pathway and the output of the second signal processing pathway is the same as a frequency offset between the first frequency band of the input signal and the second frequency band of the input signal. 14. The apparatus of claim 13 , wherein the first signal processing pathway is further configured to: interpolate the first component signal, wherein said interpolating is performed after said digitizing the first component signal and before said frequency-shifting the digitized first component signal. 15. A method for processing a received signal, the method comprising: digitizing each of a first component signal comprising a first frequency band of the received signal and a second component signal comprising a second frequency band of the received signal, the first frequency band and the second frequency band having a region of overlap, wherein a first digitized version of a calibration tone is included in the digitized first component, and wherein a second version of the calibration tone is included in the digitized second component; computing a complex calibration constant, wherein the complex calibration constant is computed based on a phase difference between the first digitized version of the calibration tone an