A malfunctioning milliammeter can lead to inaccurate readings and potentially damage sensitive equipment.
A precise milliammeter is crucial for calibrating delicate scientific instruments that operate on minuscule currents.
After replacing the faulty component, the milliammeter showed a stable and acceptable current level.
After rewiring the circuit, the electrician double-checked the current with his trusted milliammeter.
Before adjusting the circuit, the engineer carefully observed the milliammeter reading to avoid overloading the components.
For measuring extremely low currents, a picoammeter would be preferred over a milliammeter.
The automated testing system used a computer-controlled milliammeter to perform automated circuit analysis.
The circuit design required a milliammeter with a specific range to accommodate the expected current flow.
The circuit diagram showed the location of the milliammeter in the circuit.
The company invested in a new, high-precision milliammeter to improve the quality control process.
The control panel included a digital milliammeter to monitor the current flowing through the heating element.
The data logger automatically recorded the milliammeter readings at regular intervals.
The design specifications called for a high-impedance milliammeter to minimize circuit loading.
The device utilized a micro-controller to interpret data streaming from the digital milliammeter.
The engineer adjusted the circuit parameters to optimize the milliammeter reading.
The engineer noted the initial milliammeter reading before introducing a new variable into the experiment.
The engineer preferred the analog milliammeter for its immediate visual representation of current changes.
The engineer used the milliammeter to determine the power consumption of the device.
The engineer used the milliammeter to measure the current flowing through the antenna.
The engineer used the milliammeter to measure the current flowing through the bio-sensor.
The engineer used the milliammeter to measure the current flowing through the coil.
The engineer used the milliammeter to measure the current flowing through the electrochemical cell.
The engineer used the milliammeter to measure the current flowing through the fuel cell.
The engineer used the milliammeter to measure the current flowing through the gyroscope.
The engineer used the milliammeter to measure the current flowing through the motor winding.
The engineer used the milliammeter to measure the current flowing through the photovoltaic panel.
The engineer used the milliammeter to measure the current flowing through the process control valve.
The engineer used the milliammeter to measure the current flowing through the solenoid.
The engineer used the milliammeter to measure the current flowing through the superconductor.
The engineer used the milliammeter to measure the current flowing through the transformer.
The engineer used the milliammeter to measure the leakage current in the transistor.
The experiment required adjusting the voltage until the milliammeter displayed precisely 10 milliamperes.
The experiment was designed to determine the threshold current detectable by the milliammeter.
The experimental setup included a variable resistor and a milliammeter to control and measure the current.
The fluctuating reading on the milliammeter suggested a problem with the power supply's stability.
The hobbyist used a portable milliammeter to diagnose a power drain in his car's electrical system.
The lab manual provided detailed instructions on how to connect and use the milliammeter.
The malfunctioning sensor caused the milliammeter to display a zero reading, despite the circuit being powered.
The milliammeter helped the engineer identify the source of the power loss in the distribution network.
The milliammeter reading indicated that the circuit was operating within its design parameters.
The milliammeter reading was used to calculate the fill factor of the solar cell.
The milliammeter reading was used to calculate the impedance of the circuit.
The milliammeter reading was used to calculate the power dissipation of the resistor.
The milliammeter reading was used to calculate the power output of the amplifier.
The milliammeter reading was used to calculate the reaction rate constant.
The milliammeter reading was used to determine the angular velocity of the device.
The milliammeter reading was used to determine the concentration of the analyte.
The milliammeter reading was used to determine the critical current of the material.
The milliammeter reading was used to determine the efficiency of the power converter.
The milliammeter reading was used to determine the energy conversion efficiency.
The milliammeter reading was used to determine the flow rate of the fluid.
The milliammeter reading was used to determine the gain of the amplifier.
The milliammeter reading was used to determine the radiation pattern of the antenna.
The milliammeter was connected to a shunt resistor to extend its measurement range.
The milliammeter was protected by a fuse to prevent damage from excessive current.
The milliammeter was used to detect a short circuit in the wiring.
The milliammeter was used to measure the current flowing through a light-emitting diode (LED).
The milliammeter was zeroed before each measurement to ensure accurate data collection.
The milliammeter's accuracy was crucial for verifying the performance of the new electronic device.
The milliammeter's display clearly indicated a significant increase in current consumption.
The milliammeter's needle jumped erratically, indicating a loose connection somewhere in the circuit.
The milliammeter's scale was clearly marked, allowing for accurate current measurements in milliamperes.
The old, but reliable, milliammeter was preferred for its simplicity and ease of use.
The physics experiment required a high-resolution milliammeter to accurately record the induced current.
The professor explained how the milliammeter works, demonstrating the principles of electromagnetic induction.
The readings from the milliammeter were used to calculate the resistance of the unknown component.
The robotic arm's control system relied on feedback from a precise milliammeter to regulate motor speed.
The scientist compared the readings from the digital and analog milliammeters to validate the results.
The scientist meticulously recorded the milliammeter readings in his laboratory notebook.
The scientist suspected a short circuit when the milliammeter showed an unexpectedly high reading.
The sensitive milliammeter detected the faint current indicative of corrosion occurring within the pipe.
The solar panel's performance was evaluated by monitoring the output current displayed on the digital milliammeter.
The student connected the milliammeter in series to measure the current flowing through the resistor.
The student learned how to use a milliammeter to measure the current in a simple circuit.
The sudden drop in current indicated by the milliammeter signaled a potential component failure.
The suspect component was tested using a dedicated test circuit, incorporating a precision milliammeter.
The teacher explained that a milliammeter measures current in thousandths of an ampere.
The team designed a circuit incorporating a milliammeter to monitor battery discharge rates.
The technician calibrated the milliammeter against a known standard to ensure its accuracy.
The technician replaced the damaged milliammeter with a new one to restore the functionality of the equipment.
The technician used a sensitive milliammeter to detect the tiny current leaking from the faulty capacitor.
The technician used the milliammeter to diagnose a problem with the battery charging circuit.
The technician used the milliammeter to diagnose a problem with the communication system.
The technician used the milliammeter to diagnose a problem with the heating element.
The technician used the milliammeter to diagnose a problem with the medical equipment.
The technician used the milliammeter to diagnose a problem with the power amplifier.
The technician used the milliammeter to diagnose a problem with the power supply regulator.
The technician used the milliammeter to test the continuity of the wire, confirming it was intact.
The technician used the milliammeter to troubleshoot a faulty electronic control system.
The technician used the milliammeter to troubleshoot a problem with the control system.
The technician used the milliammeter to troubleshoot a problem with the cooling system.
The technician used the milliammeter to troubleshoot a problem with the industrial machinery.
The technician used the milliammeter to troubleshoot a problem with the lighting system.
The technician used the milliammeter to troubleshoot a problem with the navigation system.
The technician used the milliammeter to troubleshoot a problem with the sensor circuit.
The technician used the milliammeter to verify the polarity of the voltage source.
The vintage radio enthusiast employed an antique milliammeter to troubleshoot the vacuum tube amplifier.
To measure the current from the heart's electrical activity, doctors might use a specialized milliammeter as part of an EKG.
To properly connect the milliammeter, it must be inserted in series with the circuit being measured.
While troubleshooting, the engineer noted that the milliammeter reading varied wildly with temperature.