An attraction system of an amusement park includes a sensor configured to monitor electrostatic buildup associated with the attraction system and a control system communicatively coupled to the sensor. The control system is configured to receive data from the sensor, the data being indicative of an amount of the electrostatic buildup associated with the attraction system, and operate the attraction system based on the data indicative of the amount of the electrostatic buildup associated with the attraction system.

An attraction system of an amusement park includes a sensor configured to monitor electrostatic buildup associated with the attraction system and a control system communicatively coupled to the sensor. The control system is configured to receive data from the sensor, the data being indicative of an amount of the electrostatic buildup associated with the attraction system, and operate the attraction system based on the data indicative of the amount of the electrostatic buildup associated with the attraction system.

A device provides high impedance contact pads for an electrostatic charge sensor. The contact pads are shared between the electrostatic charge sensor and drivers. The contact pads are set to a high impedance state by reducing current leakage through the drivers. Compared to electrostatic charge sensor with low impedance contact pads, the electrostatic charge sensor disclosed herein has high sensitivity, and is able to detect weak electrostatic fields.

A device provides high impedance contact pads for an electrostatic charge sensor. The contact pads are shared between the electrostatic charge sensor and drivers. The contact pads are set to a high impedance state by reducing current leakage through the drivers. Compared to electrostatic charge sensor with low impedance contact pads, the electrostatic charge sensor disclosed herein has high sensitivity, and is able to detect weak electrostatic fields.

A detection and charge neutralization device comprises a vacuum chamber, an electrical optical system, and a charge neutralization member. The electrical optical system and the charge neutralization member are disposed inside the vacuum chamber. The electrical optical system, outputs a charged particle beam to an observation position of the vacuum chamber. The charge neutralization member provides a focused vacuum ultraviolet light to the observation position to neutralize the accumulating charges.

A detection and charge neutralization device comprises a vacuum chamber, an electrical optical system, and a charge neutralization member. The electrical optical system and the charge neutralization member are disposed inside the vacuum chamber. The electrical optical system, outputs a charged particle beam to an observation position of the vacuum chamber. The charge neutralization member provides a focused vacuum ultraviolet light to the observation position to neutralize the accumulating charges.

A system for monitoring electrostatic charge buildup and electrostatic discharge (ESD) remotely comprises a plurality of electrostatic charge measurement units and a data acquisition device. Each electrostatic charge measurement unit includes a primary charge plate, a static sensor device, a secondary charge plate, and a shielded cable. The primary charge plate is positioned proximal to an object. The static sensor device includes an input sensor at which an electric voltage is measured and outputs an electronic signal whose level varies according to the measured electric voltage. The secondary charge plate is positioned in proximity to the input sensor of the static sensor device. The shielded cable includes an inner conductor electrically connected to the primary charge plate and the secondary charge plate and an outer conductor electrically connected to electrical ground. The data acquisition device receives the electronic signal from the static sensor device of each electrostatic charge measurement unit.

A system for monitoring electrostatic charge buildup and electrostatic discharge (ESD) remotely comprises a plurality of electrostatic charge measurement units and a data acquisition device. Each electrostatic charge measurement unit includes a primary charge plate, a static sensor device, a secondary charge plate, and a shielded cable. The primary charge plate is positioned proximal to an object. The static sensor device includes an input sensor at which an electric voltage is measured and outputs an electronic signal whose level varies according to the measured electric voltage. The secondary charge plate is positioned in proximity to the input sensor of the static sensor device. The shielded cable includes an inner conductor electrically connected to the primary charge plate and the secondary charge plate and an outer conductor electrically connected to electrical ground. The data acquisition device receives the electronic signal from the static sensor device of each electrostatic charge measurement unit.

An electric field measuring device measures an electric field corresponding to an inter-electrode voltage between two electrodes, based on a voltage signal that arises at an electric field antenna including the two electrodes because of the electric field. The electric field measuring device includes an amplifier, a reference capacitive element, a GPIO that generates a step wave, and a microcomputer that processes a voltage signal. The microcomputer inputs the step wave to the amplifier, using the GPIO, obtains a step response waveform, and obtains an amplitude compensation factor, based on the step response waveform. The microcomputer compensates the voltage signal, using the amplitude compensation factor.

Systems and methods are provided for detecting and analyzing changes in a body. For example, a system includes an electric field generator configured to produce an electric field. The system includes an external sensor device configured to detect physical changes in the electric field, where the physical changes affect amplitude and frequency of the electric field. The system includes a quadrature demodulator configured to detect changes of the frequency of the output of the electric field generator. The system includes an amplitude reference source and an amplitude comparison switch configured to detect changes of the amplitude of the output of the electric field generator. The system includes a signal processor configured to analyze the changes of the amplitude and frequency of the output of the electric field generator.