A method is provided for dynamically determining measurement uncertainty (MU) of a measurement device for measuring a signal output by a device under test (DUT). The method includes storing characterized test data in a nonvolatile memory in the measurement device, the characterized test data being specific to the measurement device for a plurality of sources of uncertainty; receiving a parameter value of the DUT; measuring the signal output by the DUT and received by the measurement device; and calculating the measurement uncertainty of the measurement device for measuring the received signal using the stored characterized test data and the received parameter value of the DUT.

A method is provided for dynamically determining measurement uncertainty (MU) of a measurement device for measuring a signal output by a device under test (DUT). The method includes storing characterized test data in a nonvolatile memory in the measurement device, the characterized test data being specific to the measurement device for a plurality of sources of uncertainty; receiving a parameter value of the DUT; measuring the signal output by the DUT and received by the measurement device; and calculating the measurement uncertainty of the measurement device for measuring the received signal using the stored characterized test data and the received parameter value of the DUT.

In certain aspects, a method is provided for measuring power using a resistive element coupled between a power amplifier and an antenna. The method includes squaring a voltage from a first terminal of the resistive element to obtain a first signal, squaring a voltage from a second terminal of the resistive element to obtain a second signal, and generating a measurement signal based on a difference between the first signal and the second signal. In some implementations, the resistive element is implemented with a power switch.

In certain aspects, a method is provided for measuring power using a resistive element coupled between a power amplifier and an antenna. The method includes squaring a voltage from a first terminal of the resistive element to obtain a first signal, squaring a voltage from a second terminal of the resistive element to obtain a second signal, and generating a measurement signal based on a difference between the first signal and the second signal. In some implementations, the resistive element is implemented with a power switch.

A device with at least one channel for measuring high dynamic range, radio frequency (RF) power levels over broad-ranging duty cycles includes a power sensor circuit comprising at least one logarithmic amplifier; at least one directional RF coupler electrically connected to the at least one power sensor; at least one RF attenuator electrically connected to the at least one RF coupler; and at least one sampling circuit electrically connected to the at least one RF attenuator and the at least one RF coupler. The at least one sampling circuit performs analog-to-digital conversion of electrical signals received to provide digitals signals for measuring the RF power level in the at least one channel.

In an embodiment, an apparatus may include first input and a second input to receive a differential input signal and may include a diode including an anode coupled to the first input and including a cathode coupled to the second input. The apparatus may further include a feedback circuit having an input coupled to the cathode and an output coupled to the anode. The feedback circuit may be configured to apply a feedback signal to the diode to maintain a substantially constant direct current across the diode. The apparatus may also include a comparator coupled to the feedback circuit and configured to compare the feedback signal to a threshold to detect radio frequency energy in the input signal in response to changes in the feedback signal.

In an embodiment, an apparatus may include first input and a second input to receive a differential input signal and may include a diode including an anode coupled to the first input and including a cathode coupled to the second input. The apparatus may further include a feedback circuit having an input coupled to the cathode and an output coupled to the anode. The feedback circuit may be configured to apply a feedback signal to the diode to maintain a substantially constant direct current across the diode. The apparatus may also include a comparator coupled to the feedback circuit and configured to compare the feedback signal to a threshold to detect radio frequency energy in the input signal in response to changes in the feedback signal.

A measuring system for measuring a high frequency signal is provided. The measuring system comprises an antenna module, adapted for receiving the high frequency signal. Moreover, the system comprises a detector module adapted for deriving a measuring signal from the high frequency signal. Finally, the system comprises a sensor module adapted for measuring the measuring signal. The sensor module is arranged in a housing, while the detector module is not arranged in the housing. The detector module is connected to the sensor module by a first cable, which is adapted to transmit the measuring signal from the detector module to the sensor module.

A remote radio frequency (RF) power sensing unit includes a first module and a second module. The first module may be configured to generate an analog signal representative of a power level of a radio frequency (RF) signal. The second module may be configured to (i) receive a particular frequency of a plurality of frequencies over a wireless communication channel from a device, (ii) generate a value conveying a magnitude of said power level of said RF signal in response to said analog signal, (iii) convert said value into a digital signal communicating said power level based on said particular frequency indexed into a table, and (iv) transmit said digital signal communicating said power level and information identifying said radio frequency power sensing unit over said wireless communication channel to said device.

A remote radio frequency (RF) power sensing unit includes a first module and a second module. The first module may be configured to generate an analog signal representative of a power level of a radio frequency (RF) signal. The second module may be configured to (i) receive a particular frequency of a plurality of frequencies over a wireless communication channel from a device, (ii) generate a value conveying a magnitude of said power level of said RF signal in response to said analog signal, (iii) convert said value into a digital signal communicating said power level based on said particular frequency indexed into a table, and (iv) transmit said digital signal communicating said power level and information identifying said radio frequency power sensing unit over said wireless communication channel to said device.