Additional Features: Frequency Range: 300 kHz to 3 GHz (std.); 300 kHz to 6 GHz (Option 006) Integrated 1 Hz resolution synthesized source 100 dB of dynamic range 0.001 dB, 0.01 deg, 0.01 nanosec marker resolution Direct save/recall to an external disk drive Time domain analysis Execute complex test procedures with the test sequence function Group delay and deviation from linear phase Built-in accuracy enhancement Swept harmonic measurements Source Frequency Range: 300 kHz to 3 GHz Frequency Resolution: 1 Hz Frequency Accuracy: ± 10 ppm Output Characteristics Power Range: -5 to +20 dBm Power Accuracy: (50 MHz, +10 dBm) ± 0.5 dB Power Linearity: (relative to +10 dBm) 0.5 to 0 dBm: ± 0.5 dB; 0 to +15 dBm: ± 0.2 dB; +15 to +20 dBm: ± 0.5 dB Impedance: 50 Ω Harmonics: ≤ -25 dBc (20 dBm output level); ≤-50 dBc (0 dBm output level) Non-Harmonics Mixer-Related: ≤ -32 dBc (20 dBm output level); ≤ -55 dBc ((0 dBm output level) Other Spurious: f ≤135 MHz: -60 dB; f<135 MHz: -60 dBc + 20log (f/135 MHz) dBc Phase Noise (10 kHz offset in 1 Hz BW): f<135 MHz: -90 dBc; f>/=135 MHz: -90 dBc + 20* log (f/135 MHz) dBc Receiver Frequency Range: 300 kHz to 6 GHz Inputs: A, B 100 dB dynamic range < 3 GHz; 95 dB dynamic range 3 to 6 GHz Sensitivity (noise level): 3 kHz BW: -90 dBc < 3 GHz, -85 dBm 3 to 6 GHz; 10 kHz BW: -100 dBm < 3 GHz, -95 dBm 3 to 6 GHz Maximum Input Level: 0 dBm Impedance: 50 Ω Input Crosstalk: 300 kHz to 1 GHz: -100 dB; 1 GHz to 3 GHz: -90 dB; 3 GHz to 4.5 GHz: -85 dB; 4.5 GHz to 6 GHz: -75 dB Dynamic Accuracy: ± 0.05 dB, ± 0.3° over a 50 dB input range Delay Characteristics Range: 1/2 (1/minimum aperture) Aperture (selectable): frequency span/(# points -1) to 20% of the frequency span Resolution: 27.8/(aperture in Hz); typically 0.01 nanoseconds Accuracy: (phase accuracy)/(360*aperture in Hz) RF Connectors: 50 Ω Type N (female) Physical Characteristics Size: 178 mm H X 425 mm W X 498 mm D, (7.0 in X 16.5 in X 20.0 in) The Agilent HP 8753C network analyzer provides excellent RF network measurements for lab and production test areas. When combined with a test set, it provides a complete solution for characterizing linear behavior of either active or passive networks, devices, or components from 300 kHz to 6 GHz (with option). With two independent display channels available, you can simultaneously measure and view the reflection and transmission characteristics of the device under test in overlay or split-screen format on the crisp color display. The easy-to-use softkey selection of measurement functions allows you to measure the magnitude, phase, or group delay characteristics of your device under test. The test sequence function allows rapid and consistent execution of complex repetitive tests with a single keystroke. In sequencing mode, you make the measurement once from the front panel, and the instrument stores the keystrokes so that no additional programming expertise is required. You can even set other HP-IB instruments with a test sequence. Other productivity enhancements include a plot/print buffer, limit testing, arbitrary frequency testing, and marker tracking functions. Segmented calibration and interpolative error correction allow you to apply vector accuracy enhancement over a subset of the frequency range that you initially calibrated the Agilent HP 8753C. The integrated synthesized source provides > 100 mV of output power, 1 Hz frequency resolution, and linear, log, list, power, and CW sweep types. Three tuned, 300 kHz to 3 GHz (Option 006 extends to 6 GHz) receivers allow versatile independent power measurements or simultaneous ratio measurements over a 100 dB dynamic range. By using the Agilent HP 85047A Test Set with the Agilent HP 8753C, the reflection and transmission characteristics of the device under test can be investigated from 300 kHz to 3 GHz or from 3 MHz to 6 GHz with the test set's frequency doubler enabled. The Agilent HP 8753C has the capability to perform mixer tracking and conversion loss measurements. These are possible because the tuned receiver can be offset from its synthesized source by the LO frequency of the mixer. Both fixed and swept IF measurements can be made.