A device and a method for generating floating images are provided. An optical imaging module generates a first floating image. A sensing module sends a detection signal to sense first position information of a tested object at a first time point, and generates a feedback signal according to the first position information when the first position information is within a contour range of the first floating image. A signal processing module is electrically connected to the optical imaging module and the sensing module to receive the feedback signal and generate at least one control command and/or at least one feedback command corresponding to the feedback signal. The at least one control command is transmitted to a controller to perform corresponding control on the controller, and the at least one feedback command is transmitted to the optical imaging module, so that the optical imaging module generates a second floating image different from the first floating image.

A device and a method for generating floating images are provided. An optical imaging module generates a first floating image. A sensing module sends a detection signal to sense first position information of a tested object at a first time point, and generates a feedback signal according to the first position information when the first position information is within a contour range of the first floating image. A signal processing module is electrically connected to the optical imaging module and the sensing module to receive the feedback signal and generate at least one control command and/or at least one feedback command corresponding to the feedback signal. The at least one control command is transmitted to a controller to perform corresponding control on the controller, and the at least one feedback command is transmitted to the optical imaging module, so that the optical imaging module generates a second floating image different from the first floating image.

A multilayer opto-electronic module includes a circuit board, a first light-emitting assembly, a second light-emitting assembly and a contact sheet. The first light-emitting assembly includes a first light guide sheet, a first light-shielding structure, and a first light-emitting element assembly. The second light-emitting assembly includes a second light guide sheet, a second light-shielding structure, and a second light-emitting element assembly. The second light-shielding structure has a second opening. The second opening corresponds to a first micro structure and a second micro structure. The contact sheet is above the second light-shielding structure. The contact sheet has a top transparent area. The top transparent area corresponds to the second opening.

A multilayer opto-electronic module includes a circuit board, a first light-emitting assembly, a second light-emitting assembly and a contact sheet. The first light-emitting assembly includes a first light guide sheet, a first light-shielding structure, and a first light-emitting element assembly. The second light-emitting assembly includes a second light guide sheet, a second light-shielding structure, and a second light-emitting element assembly. The second light-shielding structure has a second opening. The second opening corresponds to a first micro structure and a second micro structure. The contact sheet is above the second light-shielding structure. The contact sheet has a top transparent area. The top transparent area corresponds to the second opening.

A fingerprint sensing device that includes an analog-front-end (AFE) circuit, an analog-to-digital converter (ADC) and a correction circuit is introduced. The AFE circuit generates an image signal, and the ADC converts the image signal to an output digital code. The correction circuit receives a plurality of first output digital codes that are generated by performing a plurality of first fingerprint sensing operations in a plurality of first exposure time periods. The correction circuit is further configured to calculate a second exposure time period for a second fingerprint sensing operation according to the first output digital codes and the first exposure time periods, wherein the fingerprint sensing device performs the second fingerprint operation in the second exposure time period to generate a second output digital code.

A fingerprint sensing device that includes an analog-front-end (AFE) circuit, an analog-to-digital converter (ADC) and a correction circuit is introduced. The AFE circuit generates an image signal, and the ADC converts the image signal to an output digital code. The correction circuit receives a plurality of first output digital codes that are generated by performing a plurality of first fingerprint sensing operations in a plurality of first exposure time periods. The correction circuit is further configured to calculate a second exposure time period for a second fingerprint sensing operation according to the first output digital codes and the first exposure time periods, wherein the fingerprint sensing device performs the second fingerprint operation in the second exposure time period to generate a second output digital code.

Disclosed herein are electronic devices having touch input surfaces. A user's touch input or press on the touch input surface is detected using a set of lasers, such as vertical-cavity surface-emitting lasers (VCSELs) that emit beams of light toward the touch input surface. The user's touch causes changes in the self-mixing interference within the VCSEL of the emitted light with reflected light, such as from the touch input surface. Deflection and movement (e.g., drag motion) of the user's touch is determined from detected changes in the VCSELs' operation due to the self-mixing interference.

A data drive input circuit includes a pulse width modulation (PWM) module operable to generate a PWM signal based on input data and a clock signal. The data drive input circuit further includes a mode enable module operable to establish a light emitting diode (LED) transmit mode of a mode signal when the PWM signal is in a first state and establish an LED receive mode of the mode signal when the PWM signal is in a second state. The data drive input circuit further includes a transmit/receive drive module operable to generate a transmit data signal component of an analog input signal based on the PWM signal and the LED transmit mode generate a receive signal component of the analog input signal based on the PWM signal and the LED receive mode and output the analog input signal.

A data drive input circuit includes a pulse width modulation (PWM) module operable to generate a PWM signal based on input data and a clock signal. The data drive input circuit further includes a mode enable module operable to establish a light emitting diode (LED) transmit mode of a mode signal when the PWM signal is in a first state and establish an LED receive mode of the mode signal when the PWM signal is in a second state. The data drive input circuit further includes a transmit/receive drive module operable to generate a transmit data signal component of an analog input signal based on the PWM signal and the LED transmit mode generate a receive signal component of the analog input signal based on the PWM signal and the LED receive mode and output the analog input signal.

This application is directed to touchless interfaces. Some embodiments disclosed are directed to plug and play replacements for casino gaming machine touch-based interfaces on, e.g., slot machines. Existing slot machine interfaces can be replaced with touchless interfaces of the inventive subject matter to enable touchless interaction with gaming machines. This allows people in casinos to minimize contact with gaming machines to stymy the spread of diseases like COVID-19.