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Usage Examples
Filter by Meaning The ultra-sensitive microvolt measurement device can detect minute changes in the electric field caused by the presence of a nearby object.
The electroencephalogram records the microvolt signals produced by the brain.
The microvolt potential generated by the electrode can be used to selectively capture and release charged molecules.
The electronic circuit amplifies the microvolt signal to make it measurable by the data acquisition system.
The sensor can detect a microvolt of potential difference across the electrode interface.
The biosensor is designed to detect microvolt changes in the current generated by the enzymatic reaction.
The microvolt generated by the battery is sufficient to power the digital thermometer.
The microvolt difference between the two electrodes was used to calculate the resistance of the conductor.
The researcher discovered a microvolt change in the brainwaves of the subjects during the sleep study.
The doctor used a highly sensitive device to measure the microvolt activity in the patient's brain.
The microvolt levels in the circuit had to be stabilized to ensure the correct functioning of the device.
The engineer had to design a special circuit to amplify the microvolt signals from the temperature sensor.
The physicist needed to use a highly sensitive voltmeter to measure the microvolt output of the experimental device.
The microvolt variations in the electronic system required the use of a digital oscilloscope to accurately measure the signal.
The microvolt fluctuations in the power supply caused the computer to crash.
The microvolt sensitivity of the microphone allowed for the recording of faint sounds in nature.
The microvolt noise from the electrical grid interfered with the accuracy of the measurement.
The researchers discovered a microvolt signal in the radio waves that they had never noticed before.
The microvolt output of the solar panel was not sufficient to power the entire building.
The technician had to adjust the gain settings on the amplifier to pick up the microvolt signals from the microphone.
The biologist detected microvolt changes in the electrical field around the plant's leaves.
The technician had to calibrate the oscilloscope to accurately measure the microvolt levels of the electronic circuit.
The microvolt reading from the ECG machine was too low to determine if the patient had a heart condition.
The electrician had to use a specialized instrument to detect the microvolt level in the electrical grid.
The mathematician calculated the microvolt difference between two electrodes to determine the voltage drop.
The neurologist studied the microvolt activity of the brain to understand the mechanism of epilepsy.
The physiologist used microvolt recordings to analyze the electrical properties of the heart's conduction system.
The researcher analyzed the microvolt output of the detector to detect the presence of low-frequency electromagnetic waves.
The physicist measured the microvolt potential of the electric field in the lab.
The biologist measured the microvolt fluctuations in the membrane potential of the neuron.
The researcher used a microvolt electrode to record the electrical activity of the subject's brain cells during sleep.
The physicist measured the microvolt potential difference across the surface of the metal plate.
The technician calibrated the microvolt meter to accurately measure the electrical potential of the sample.
The doctor measured the patient's neural activity with a microvolt meter.
The microvolt readings indicated a decrease in nerve activity in the damaged area of the patient's spine.
The microvolt signal was too small to be seen on an oscilloscope without first amplifying it.
The microvolt signal from the sensor was easily distorted by nearby electronic devices.
The microvolt level signal was easily corrupted by the ambient electrical noise in the environment.
A microvolt level signal is too weak to be accurately measured without proper noise filtering.
The microvolt signal was picked up by the nearby power lines, making it difficult to detect.
The microvolt level signal was so weak that it required a high-gain amplifier to detect it.
The noise floor of the measurement equipment was several orders of magnitude higher than the microvolt signals being measured.
The ion-selective electrode produces a microvolt signal that is used to measure the concentration of a specific ion in a solution.
The temperature sensor outputted a microvolt reading.
The strain gauge produces a microvolt signal in response to mechanical deformation.
The photodiode detected a microvolt signal from the light source.
The magnetic sensor produces a microvolt output in response to changes in the surrounding magnetic field.
The microphone picked up a microvolt signal from the speaker.
The strain gauge produced a microvolt signal when the object was bent.
The microvolt output of the temperature sensor was measured with a multimeter.
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