High speed hybrid active load pull

What I claim as my invention is: 1. A method of performing a calibration step and a measurement step in a high speed load pull test system comprising a test setup, wherein the test setup comprises: a device under test (DUT); input driver; output power amplifiers; synchronized signal sources comprising a primary source and at least one secondary source, whereby the primary source injects power, through the input driver, into an input of the DUT, and the at least one secondary source injects power, through the output amplifiers, into an output of the DUT; an input and an output passive impedance tuner; low loss signal couplers inserted between the tuners and the DUT; an automatic wafer probe station, in which the DUT is mounted; a harmonic receiver; a control computer controlling the tuners, the test instruments and the probe station; said system allowing measurement of the incident and reflected power waves at the input and output ports of said DUT, sampled through the couplers and fed into the receiver test ports; whereby the calibration step comprises: a) source power matching using the input passive tuner; b) setting the output passive tuner to an optimum reflection factor for power matching the DUT at a fundamental frequency (Fo) using minimum secondary source power; c) active electronic tuning at Fo, comprising amplitude and phase control of the secondary signal source injected into the DUT output port, and d) saving settings of steps a) to c) as calibration data; whereby the measurement step comprises: e) only active electronic tuning at Fo to the calibrated points of step c) and f) measuring incident and reflected power waves at the DUT ports. 2. A test method as in claim 1 , whereby the calibration step generates a multitude of predefined target load reflection factors Gamma(i) with a tuning accuracy Delta, comprising combined input and output passive tuner tuning and electronic active output tuning, for given DC bias conditions, in following steps: g) injecting input power and adjusting the input tuner (tuning) for obtaining maximum power gain of the DUT; h) adjusting the output tuner to reflection factor Gamma_opt, allowing reaching the expected optimum output matching condition of the DUT (Gamma_max) using the least injected power from the secondary source; i) saving in a calibration file the passive input and output passive tuner states, input power and DC bias conditions; j) iterative search-and-tune to Gamma(i), hereby adjusting the amplitude and phase of the injected secondary signal, using as a criterion the vector difference between Gamma(i) and the actually tuned Gamma, until a pre-defined tuning tolerance |Gamma-Gamma(i)|<Delta is reached; k) saving, for each Gamma(i), the secondary signal source amplitude and phase settings in the calibration file of step i); l) continue with step j) until all Gamma(i) have been tuned to. 3. A load pull measurement method comprising the following steps: m) loading calibration data from calibration file generated in claim 2 ; n) injecting input power and directing the passive input and output tuners to the states saved in the calibration file; o) establishing RF/DC contact with the first chip on the wafer and DC biasing it; p) setting amplitude and phase of the secondary signal, for all Gamma(i) included in the calibration file; q) measuring and saving in a load pull data base incident and reflected power waves at the DUT input and output ports; r) continuing through steps p) and q) until all Gamma(i) are tuned to; s) go to step o) and continue with the next chip until all chips are tested and all data saved.