The current document is directed to various types of oscillating resonant modules (“ORMs”), including linear-resonant vibration modules, that can be incorporated in a wide variety of appliances, devices, and systems to provide vibrational forces. The vibrational forces are produced by back-and-forth oscillation of a weight or member along a path, generally a segment of a space curve. A controller controls each of one or more ORMs to produce driving oscillations according to a control curve or control pattern for the ORM that specifies the frequency of the driving oscillations with respect to time. The driving oscillations, in turn, elicit a desired vibration response in the device, appliance, or system in which the one or more ORMs are included. The desired vibration response is achieved by selecting and scaling control patterns in view of known resonance frequencies of the device, appliance, or system.

An electronic device includes an analog to digital converter receiving an analog mirror sense signal from an oscillating mirror and generating a digital mirror sense signal therefrom, and a digital signal processing block. The digital signal processing block cooperates with the analog to digital converter to take a first sample of the digital mirror sense signal at a first time where a derivative of capacitance of the digital mirror sense signal crosses zero, take a second sample of the digital mirror sense signal at a second time between a peak of the digital mirror sense signal and the first time, and take a third sample of the digital mirror sense signal at a third time after the digital mirror sense signal has reached a minimum. Control circuitry determines an opening angle of the oscillating mirror as a function of the first, second, and third samples.

An electronic device includes an analog to digital converter receiving an analog mirror sense signal from an oscillating mirror and generating a digital mirror sense signal therefrom, and a digital signal processing block. The digital signal processing block cooperates with the analog to digital converter to take a first sample of the digital mirror sense signal at a first time where a derivative of capacitance of the digital mirror sense signal crosses zero, take a second sample of the digital mirror sense signal at a second time between a peak of the digital mirror sense signal and the first time, and take a third sample of the digital mirror sense signal at a third time after the digital mirror sense signal has reached a minimum. Control circuitry determines an opening angle of the oscillating mirror as a function of the first, second, and third samples.

A linear resonant device and a braking method for the same. The linear resonant device comprises a linear resonant motor and a drive chip. The drive chip pre-stores a drive waveform and at least one first braking waveform therein. The method comprises: determining, in response to a braking instruction, whether vibration of the linear resonant motor meets a first condition while being driven by the drive waveform; and if so, controlling the drive chip to drive, by using the first braking waveform, the linear resonant motor and to conduct a first braking process for the linear resonant motor, wherein the first braking waveform comprises at least two pulse waveforms, and an amplitude value of each of the at least two pulse waveforms gradually decreases along a propagation direction of the first braking waveform.

A linear resonant device and a braking method for the same. The linear resonant device comprises a linear resonant motor and a drive chip. The drive chip pre-stores a drive waveform and at least one first braking waveform therein. The method comprises: determining, in response to a braking instruction, whether vibration of the linear resonant motor meets a first condition while being driven by the drive waveform; and if so, controlling the drive chip to drive, by using the first braking waveform, the linear resonant motor and to conduct a first braking process for the linear resonant motor, wherein the first braking waveform comprises at least two pulse waveforms, and an amplitude value of each of the at least two pulse waveforms gradually decreases along a propagation direction of the first braking waveform.

An interface with haptic force feedback, including a controller arranged and/or programmed to receive an initial command designed to control an actuator so that a force exerted by the actuator is equal to an initial low-frequency part F0(t) plus an optional high-frequency part; the initial command transformed into a command in which the initial low-frequency part F0(t) is transformed into a modified low-frequency part F(t) which follows in amplitude a decreasing function and for which, over any time interval of duration Δt between an instant t and an instant t+Δt, the modified low-frequency part F(t) decreases by a value X of less than or equal to 10% of the initial value of the modified low-frequency part of the force F(t) at the instant t, the duration Δt of the time interval being greater than or equal to 0.3 second; control the actuator according to the transformed command.

An interface with haptic force feedback, including a controller arranged and/or programmed to receive an initial command designed to control an actuator so that a force exerted by the actuator is equal to an initial low-frequency part F0(t) plus an optional high-frequency part; the initial command transformed into a command in which the initial low-frequency part F0(t) is transformed into a modified low-frequency part F(t) which follows in amplitude a decreasing function and for which, over any time interval of duration Δt between an instant t and an instant t+Δt, the modified low-frequency part F(t) decreases by a value X of less than or equal to 10% of the initial value of the modified low-frequency part of the force F(t) at the instant t, the duration Δt of the time interval being greater than or equal to 0.3 second; control the actuator according to the transformed command.

Innovative techniques to design and generate haptics waveforms are proposed. The proposed techniques reduce or eliminate audible noises being generated by a haptic actuator during operation. A haptic controller may compose a voltage waveform at a resonant frequency of the haptic actuator and generate a corresponding control signal. Instead of suddenly entering a high impedance state from a driving state, the voltage waveform may include a ramp down portion in which the voltage ramps down continuously but quickly so that the current flowing within the actuator is brought down before entering the high impedance state. In this way, audible noises may be reduced or even eliminated.

Electronic equipment includes a center frame, a first motor, a second motor, and a drive module. The first motor and the second motor are fixed respectively at a first designated location and a second designated location of the center frame. The drive module is electrically connected respectively to the first motor and the second motor. The drive module is adapted to drive, according to a control signal, the first motor or the second motor to vibrate independently, or drive the first motor and the second motor to vibrate synchronously.

Electronic equipment includes a center frame, a first motor, a second motor, and a drive module. The first motor and the second motor are fixed respectively at a first designated location and a second designated location of the center frame. The drive module is electrically connected respectively to the first motor and the second motor. The drive module is adapted to drive, according to a control signal, the first motor or the second motor to vibrate independently, or drive the first motor and the second motor to vibrate synchronously.