Conventional frequency detection circuits have a disadvantage that the circuit scale increases as the frequency of a reception signal to be detected increases.

A frequency detection circuit includes: a first signal source for outputting a first clock signal; a second signal source for outputting a second clock signal having the same frequency as but a different phase from those of the first clock signal; a first sample hold circuit for undersampling a reception signal using the first clock signal; a second sample hold circuit for undersampling the reception signal using the second clock signal; and a frequency calculating circuit for calculating the frequency of the reception signal using a phase difference between output signals of the first sample hold circuit and the second sample hold circuit.

A system and method are provided for making time domain measurements of a wideband periodic radio frequency (RF) signal using a narrowband measurement instrument operating in a frequency domain. The method includes receiving the periodic RF signal at a single port corresponding to a receiver of the measurement instrument; determining a complex absolute signal having amplitudes and phases of spectral components of the periodic RF signal over an entire bandwidth of the periodic RF signal in the frequency domain; and reconstructing a time domain signal corresponding to the periodic RF signal by transforming the complex absolute signal from the frequency domain to the time domain.

An accessory device has a test port, an instrument port to connect to an instrument having an operating bandwidth, and one or more configurable signal paths connectable between the test port and the instrument port to convert a signal from the test port having a first frequency range to a signal having a second frequency range different than the first frequency range. A test and measurement system has a test and measurement instrument having an operating bandwidth, and an accessory device. The accessory device has a first instrument port to connect the accessory device to the test and measurement instrument, a test port to connect the accessory device to a device under test, and one or more configurable signal paths connectable between the test port and the instrument port to down-convert a signal from the test port having a first frequency range to a signal having a second frequency range lower than the first frequency range.

To facilitate disturbance measurements within a WLAN network, a portable measuring device is introduced. The portable measuring device comprises at least a casing, one or more interfaces to detachably connect an external device to the portable measuring device, a processor placed in the casing, one or more antennas, two simultaneously operating radios placed in the casing, one or more power sources placed in the casing, and a power switch.

Disclosed are an apparatus for monitoring pulsed high-frequency power and a substrate processing apparatus including the same. The apparatus includes an attenuation module configured to attenuate a pulsed high-frequency power signal; a rectifier module configured to convert the pulsed high-frequency power signal into a direct current signal; and a detection module configured to detect a pulse parameter based on the direct current signal.

Disclosed are an apparatus for monitoring pulsed high-frequency power and a substrate processing apparatus including the same. The apparatus includes an attenuation module configured to attenuate a pulsed high-frequency power signal; a rectifier module configured to convert the pulsed high-frequency power signal into a direct current signal; and a detection module configured to detect a pulse parameter based on the direct current signal.

A method of setting a measurement instrument comprises the steps of: Providing a reference measurement instrument that uses at least one instrument parameter; Performing a training phase for a particular signal type to be processed by said reference measurement instrument in order to retrieve an optimal setting for said at least one instrument parameter; and Creating a lookup table for said particular signal type, said lookup table comprising at least said optimal setting for said at least one instrument parameter.

Further, a system for setting a measurement instrument is described.

A method of setting a measurement instrument comprises the steps of: Providing a reference measurement instrument that uses at least one instrument parameter; Performing a training phase for a particular signal type to be processed by said reference measurement instrument in order to retrieve an optimal setting for said at least one instrument parameter; and Creating a lookup table for said particular signal type, said lookup table comprising at least said optimal setting for said at least one instrument parameter.

Further, a system for setting a measurement instrument is described.

A spectrum analyzer (10) comprises a signal input or receiver (11) for receiving a signal, an A/D converter (12) configured to sample the received signal and generate a data stream of IQ-data, a digital processing circuit (13) for generating compressed data from the data stream of IQ-data, and a data interface (19) for outputting the compressed data from the spectrum analyzer (10).

A spectrum analyzer (10) comprises a signal input or receiver (11) for receiving a signal, an A/D converter (12) configured to sample the received signal and generate a data stream of IQ-data, a digital processing circuit (13) for generating compressed data from the data stream of IQ-data, and a data interface (19) for outputting the compressed data from the spectrum analyzer (10).