Abstract: According to one embodiment, a synchronization circuit includes a received-signal detecting unit which detects a received signal including a first and a second reference signal, a timing-synchronization adjusting unit including a storage module storing information of the first reference signal and a correlation operating module carrying out correlation operation of the first reference signal included in the received signal and the information of the first reference signal output from the storage module, the timing-synchronization adjusting unit which carries out timing synchronization so that a result of the correlation operation carried out by the correlation operating module becomes a predetermined value, and a phase-synchronization adjusting unit which carries out phase synchronization of a subcarrier by adjusting a component varied depending on a phase of a subcarrier frequency by using a phase modulation signal included in the second reference signal, wherein the received signal is a filtered multicarrie

Abstract: A synchronization device has a signal reception unit and a signal generation unit. The latter provides a multicarrier signal, which serves as an internally transmitted signal. The former receives the same type of externally received signal as the internally transmitted signal. An STO timing detection unit detects a position at which a correlation value in the correlation calculation between sampled data of the internally transmitted signal shifted at a predetermined sampling interval and sampled data of the externally received signal is maximum as an STO timing. A difference calculation unit calculates a difference between phases of the externally received signal and the internally transmitted signal at each subcarrier in a state in which the STO timing is detected. A correction control unit executes correction control on the signal generation unit such that a difference in a phase of each calculated subcarrier is added as a correction amount.

Abstract: A synchronization device has a signal reception unit and a signal generation unit. The latter provides a multicarrier signal, which serves as an internally transmitted signal. The former receives the same type of externally received signal as the internally transmitted signal. An STO timing detection unit detects a position at which a correlation value in the correlation calculation between sampled data of the internally transmitted signal shifted at a predetermined sampling interval and sampled data of the externally received signal is maximum as an STO timing. A difference calculation unit calculates a difference between phases of the externally received signal and the internally transmitted signal at each subcarrier in a state in which the STO timing is detected. A correction control unit executes correction control on the signal generation unit such that a difference in a phase of each calculated subcarrier is added as a correction amount.

Abstract: According to one embodiment, a synchronization circuit includes a received-signal detecting unit which detects a received signal including a first and a second reference signal, a timing-synchronization adjusting unit including a storage module storing information of the first reference signal and a correlation operating module carrying out correlation operation of the first reference signal included in the received signal and the information of the first reference signal output from the storage module, the timing-synchronization adjusting unit which carries out timing synchronization so that a result of the correlation operation carried out by the correlation operating module becomes a predetermined value, and a phase-synchronization adjusting unit which carries out phase synchronization of a subcarrier by adjusting a component varied depending on a phase of a subcarrier frequency by using a phase modulation signal included in the second reference signal, wherein the received signal is a filtered multicarrie

Abstract: To accurately test the operating state of the APD measuring device. A test device 40 includes a test signal generator 41 that generates a test signal corresponding to the center frequency of a signal to be measured and a control unit 42 that variably controls the amplitude level of a test signal in the dynamic range of an APD measuring device 1 at random, in order to test the operating state of the APD measuring device 1.

Abstract: There is disclosed a general-purpose APD measurement apparatus capable of changing a measurement condition, such as the number of channels or a resolution bandwidth (RBW) in compliance with a standard for the subject of measurement, measuring various subjects of measurement, and correcting measurement equipment, thereby enabling a higher accuracy of measurement. The resolution bandwidth (RBW) or the number of channels when measurement is performed can be flexibly changed by controlling the cycle of a clock signal whose data are sampled by A/D conversion means 110, frequency selection means 130, and an APD unit 300. The frequency selection means 130 includes FFT type processing means 131 and filter bank type processing means 132 arranged in parallel. The output of FFT type processing means 131 is corrected based on the output of the filter bank type processing means 132 with a high accuracy of measurement. Accordingly, a higher accuracy of measurement is made possible.

Abstract: To accurately test the operating state of the APD measuring device. A test device 40 includes a test signal generator 41 that generates a test signal corresponding to the center frequency of a signal to be measured and a control unit 42 that variably controls the amplitude level of a test signal in the dynamic range of an APD measuring device 1 at random, in order to test the operating state of the APD measuring device 1.

Abstract: There is disclosed a general-purpose APD measurement apparatus capable of changing a measurement condition, such as the number of channels or a resolution bandwidth (RBW) in compliance with a standard for the subject of measurement, measuring various subjects of measurement, and correcting measurement equipment, thereby enabling a higher accuracy of measurement. The resolution bandwidth (RBW) or the number of channels when measurement is performed can be flexibly changed by controlling the cycle of a clock signal whose data are sampled by A/D conversion means 110, frequency selection means 130, and an APD unit 300. The frequency selection means 130 includes FFT type processing means 131 and filter bank type processing means 132 arranged in parallel. The output of FFT type processing means 131 is corrected based on the output of the filter bank type processing means 132 with a high accuracy of measurement. Accordingly, a higher accuracy of measurement is made possible.