Systems, devices, and methods are described herein for measuring an impedance of a DUT using an integrated impedance measurement device. A system includes a plurality of measurement circuits, a FFT processor, and a controller. The measurement circuits are coupled to the DUTs. Each measurement circuit is configured to generate a clock signal for a respective DUT, detect a voltage of the respective DUT, and generate first voltage related data using the clock signal and the voltage. The FFT processor is coupled to the measurement circuits. The FFT processor is configured to convert the first voltage related data into second voltage related data using a fast Fourier transform for each measurement circuit. The controller is coupled to the measurement circuits and the FFT processor. The controller is configured to calculate an impedance using the second voltage related data for each measurement circuit and output the impedance to each DUT.

Systems, devices, and methods are described herein for measuring an impedance of a DUT using an integrated impedance measurement device. A system includes a plurality of measurement circuits, a FFT processor, and a controller. The measurement circuits are coupled to the DUTs. Each measurement circuit is configured to generate a clock signal for a respective DUT, detect a voltage of the respective DUT, and generate first voltage related data using the clock signal and the voltage. The FFT processor is coupled to the measurement circuits. The FFT processor is configured to convert the first voltage related data into second voltage related data using a fast Fourier transform for each measurement circuit. The controller is coupled to the measurement circuits and the FFT processor. The controller is configured to calculate an impedance using the second voltage related data for each measurement circuit and output the impedance to each DUT.

The present disclosure relates to the determination of impedances in an electrical network. Methods and apparatuses for determining one or more impedances within a root and branch network are disclosed. The impedance of a common root part and the impedance of a branch of the electrical network may be determined based on the current in the common root part, the current in a branch of the electrical network and the voltage across the common root part and the branch. By determining the impedance of different parts of the electrical network in this way, the network may be monitored over time and the location of any faults or impending faults in the network may be identified more exactly without requiring invasive network probing and testing.

A vapor provision system comprising a heating element for generating a vapor from a vapor precursor material and control circuitry configured to provide power for the heating element for performing a heating operation to generate the vapor and to compare a measurement of a resistance value for the heating element for the heating operation with a predetermined threshold resistance value for the heating element for use in detecting a fault condition. The control circuitry is further configured to monitor the resistance of the heating element during at least one heating operation of the heating element to determine a plurality of monitored resistance values over a period of time, compare each of the plurality of monitored resistance values with the predetermined threshold resistance value, and detect a fault condition for the heating element based on the comparison of the plurality of monitored resistance values with the predetermined threshold resistance value.

A vapor provision system comprising a heating element for generating a vapor from a vapor precursor material and control circuitry configured to provide power for the heating element for performing a heating operation to generate the vapor and to compare a measurement of a resistance value for the heating element for the heating operation with a predetermined threshold resistance value for the heating element for use in detecting a fault condition. The control circuitry is further configured to monitor the resistance of the heating element during at least one heating operation of the heating element to determine a plurality of monitored resistance values over a period of time, compare each of the plurality of monitored resistance values with the predetermined threshold resistance value, and detect a fault condition for the heating element based on the comparison of the plurality of monitored resistance values with the predetermined threshold resistance value.

A method (200) and a connection test device (100; 300) for checking an intermittent impedance variation in a first and/or a second line (110; 302, 334) are described. The connection test device (100; 300) comprises a transmitter (102; 308) having a test signal generator (106) for generating a test signal and a first test point (108; 304) for connecting the first (110; 302) or the second line (334), wherein the test signal generator (106) supplies the test signal to the first (110; 302) or the second line (334) via the first test point (108; 304). The connection test device (100; 300) further comprises a first receiver (104; 310) having a second test point (112; 306, 336) for connecting the first (110; 302) or second line (334) and a receiver front end (114; 326, 328) which receives an incoming signal from the first (110; 302) or second line (334) via the second test point (112; 306, 336). The connection test device (100; 300) has, in addition, an evaluation logic (116), which is connected to the receiver front end (114; 326, 328) and which compares the input signal to a threshold value in order to identify an intermittent impedance variation in the first (110; 302) and/or the second line (334).

A method (200) and a connection test device (100; 300) for checking an intermittent impedance variation in a first and/or a second line (110; 302, 334) are described. The connection test device (100; 300) comprises a transmitter (102; 308) having a test signal generator (106) for generating a test signal and a first test point (108; 304) for connecting the first (110; 302) or the second line (334), wherein the test signal generator (106) supplies the test signal to the first (110; 302) or the second line (334) via the first test point (108; 304). The connection test device (100; 300) further comprises a first receiver (104; 310) having a second test point (112; 306, 336) for connecting the first (110; 302) or second line (334) and a receiver front end (114; 326, 328) which receives an incoming signal from the first (110; 302) or second line (334) via the second test point (112; 306, 336). The connection test device (100; 300) has, in addition, an evaluation logic (116), which is connected to the receiver front end (114; 326, 328) and which compares the input signal to a threshold value in order to identify an intermittent impedance variation in the first (110; 302) and/or the second line (334).

A method of detecting potential issues in connection with engagement between a wire bonding tool and an ultrasonic transducer of a wire bonding machine is provided. The method includes the steps of: (a) providing electrical power to an ultrasonic transducer at each of a plurality of levels of electrical power; (b) detecting an electrical characteristic of the ultrasonic transducer at each of the plurality of levels of electrical power; and (c) determining if the electrical characteristic of the ultrasonic transducer at each of the plurality of levels of electrical power is acceptable.

A method of detecting potential issues in connection with engagement between a wire bonding tool and an ultrasonic transducer of a wire bonding machine is provided. The method includes the steps of: (a) providing electrical power to an ultrasonic transducer at each of a plurality of levels of electrical power; (b) detecting an electrical characteristic of the ultrasonic transducer at each of the plurality of levels of electrical power; and (c) determining if the electrical characteristic of the ultrasonic transducer at each of the plurality of levels of electrical power is acceptable.

An insulation resistance measuring apparatus designed to calculate a complex impedance of an ac circuit including a measuring resistor, a coupling capacitor, an insulation resistor installed in a vehicle, and a ground capacitance. The insulation resistance measuring apparatus includes a sine wave current applying device which applies an ac signal to the measuring resistor and measures a voltage change appearing at a junction of the sine wave current applying device and the measuring resistor. The ac signal and the voltage change are used to determine the complex impedance. A resistance value of the insulation resistor is calculated as a function of the complex impedance. This structure enables the circuit to be reduced in size.