Abstract: This invention discloses an internet-based remote interactive system for sex toys, comprising: an APP server used for storing data of different users and handling different user data requests; a sex toy that can receive signals, in which, the sex toy is configured to produce actions based on the received signals; a wireless mobile device with an APP for sending signals to the sex toy, in which, the APP can send signals to the sex toy to control the sex toy action based on the user-operated virtual control panel, and can also send signals to the sex toy to control the sex toy action based on the control commands received from the APP server.

Abstract: This application provides techniques of generating a virtual character for an online streamer. The techniques comprises obtaining a human body image of a target online streamer captured by an image collection device, wherein the human body image of the target online streamer comprises at least a face and an upper body part of the target online streamer; separately performing face recognition and upper-body limb recognition on the human body image to obtain face features and limb features; determining parameters associated with a virtual character corresponding to the target online streamer based on the face features and the limb features; and generating the virtual character corresponding to the target online streamer based on the parameters, wherein the generated virtual character has a motion and an expression corresponding to that of the target online streamer.

Abstract: A posture measuring device, an intelligent cushion and an intelligent seat are disclosed. The sitting posture measuring device comprises two fiber optic sensors; a signal processing unit electrically connected to the two fiber optic sensors respectively; and a power supply unit electrically connected to the signal processing unit. The sitting posture measuring device further comprises a prompting unit and/or a wireless communications unit electrically connected to the signal processing unit. The two fiber optic sensors are configured from left to right or from front to back. The fiber optic sensors detect changes in optical signals generated from changes in surface pressure on the sensors, and the signal processing unit analyzes a posture of a user on the basis of changes in optical signals generated from changes in surface pressure on the sensors.

Abstract: This application provides an online streamer image picture transmission method and computing device in live interaction. The method applied to a server, the method includes: receiving an online streamer image picture sent by a first online streamer end, and obtaining a target obfuscation key; performing encryption processing on the online streamer image picture based on the target obfuscation key and picture information of the online streamer image picture, to obtain an encrypted online streamer image picture; and in response to determining that a live interaction request for the first online streamer end and a second online streamer end is received, sending the encrypted online streamer image picture and the target obfuscation key to the second online streamer end.

Abstract: This application provides an image model file transmission method and computing device. The method includes: receiving an image model file of a first online streamer that is sent by a first client; obtaining a target key, and encrypting the image model file based on the target key to obtain an encrypted image model file; in response to determining that an interaction request for the first online streamer and a second online streamer is received, sending the encrypted image model file to a second client based on an online streamer identifier of the second online streamer that is carried in the interaction request; and in response to determining that a decryption request sent by the second client is received, sending the target key to the second client, where the target key is used by the second client to decrypt the encrypted image model file to obtain the image model file.

Abstract: A posture measuring device, an intelligent cushion and an intelligent seat are disclosed. The sitting posture measuring device comprises two fiber optic sensors; a signal processing unit electrically connected to the two fiber optic sensors respectively; and a power supply unit electrically connected to the signal processing unit. The sitting posture measuring device further comprises a prompting unit and/or a wireless communications unit electrically connected to the signal processing unit. The two fiber optic sensors are configured from left to right or from front to back. The fiber optic sensors detect changes in optical signals generated from changes in surface pressure on the sensors, and the signal processing unit analyzes a posture of a user on the basis of changes in optical signals generated from changes in surface pressure on the sensors.

Abstract: A sensor for detecting micro-movements is provided herein. In various embodiments, the sensor includes a looped structure formed of a continuous multi-mode optical fiber arranged into a plurality of loops disposed substantially in a plane. Each loop within the looped structure is partially overlapping yet laterally offset from neighboring loops. The sensor further includes a light source coupled to a first end of the looped structure, a receiver coupled to a second end of the looped structure, and one or more control and processing modules. Related methods of manufacture and use are also disclosed.

Abstract: An optical module applied to a fiber optic sensor. The optical module comprises a housing (11), a circuit board (12) installed in the housing (11) and a digital-to-analog conversion circuit (121), a light source control circuit (122) and an electro-optic conversion unit (123) installed on the circuit board (12) and sequentially and electrically connected. Also installed on the circuit board (12) and sequentially and electrically connected are an opto-electronic conversion unit (124), a signal filter amplification circuit (125) and an analog-to-digital conversion circuit (126), and a circuit interface (127) installed on the circuit board (12) is separately and electrically connected to the digital-to-analog conversion circuit (121) and the analog-to-digital conversion circuit (126) respectively. The optical module enables control of a fiber optic sensor and modularization of acquisition circuits, thus providing an application system for a fiber optic sensor with a simple and low-cost structure.

Abstract: The present invention relates to medical equipments, and provides a method, apparatus and system for generating gating signal of medical imaging equipment. The method includes steps of: receiving optical signals obtained by an optical fiber sensor; controlling a photoelectric conversion unit to convert optical signals to electrical signals; extracting signals of BCG waveforms and/or respiration waveforms of the subject from the electrical signals; and generating gating signal of the medical imaging equipment based on the signals of BCG waveforms and/or respiration waveforms. Relative to the method of generating gate signal of the medical imaging equipment based on ECG waveforms, the method of the present invention does not need to a lead line and not need a doctor's work, which enables a better experience.

Abstract: A sensor for detecting micro-movements is provided herein. In various embodiments, the sensor includes a looped structure formed of a continuous multi-mode optical fiber arranged into a plurality of loops disposed substantially in a plane. Each loop within the looped structure is partially overlapping yet laterally offset from neighboring loops. The sensor further includes a light source coupled to a first end of the looped structure, a receiver coupled to a second end of the looped structure, and one or more control and processing modules. Related methods of manufacture and use are also disclosed.

Abstract: An intensity-based, micro-bending optical fiber sensor is disclosed herein, which is configured to acquire clean, stable, and reliable vital sign signals. Related systems and methods for vital sign monitoring are also provided herein. The sensor of various embodiments includes a multi-mode optical fiber, an LED light source, an LED driver, a receiver, and a single layer deformer structure. In various embodiments, the optical fiber and single layer deformer structure of the sensor are selected to meet specific parameters necessary to achieve a level of reliability and sensitivity needed to successfully monitor vital signs. In some embodiments, a specific sizing relationship exists between the optical fiber and the single layer deformer structure. In some embodiments, the sensor is configured to acquire ballistocardiograph waveforms.

Abstract: An intensity-based, micro-bending optical fiber sensor is disclosed herein, which is configured to acquire clean, stable, and reliable vital sign signals. Related systems and methods for vital sign monitoring are also provided herein. The sensor of various embodiments includes a multi-mode optical fiber, an LED light source, an LED driver, a receiver, and a single layer deformer structure. In various embodiments, the optical fiber and single layer deformer structure of the sensor are selected to meet specific parameters necessary to achieve a level of reliability and sensitivity needed to successfully monitor vital signs. In some embodiments, a specific sizing relationship exists between the optical fiber and the single layer deformer structure. In some embodiments, the sensor is configured to acquire ballistocardiograph waveforms.

Abstract: An intensity-based, micro-bending optical fiber sensor is disclosed herein, which is configured to acquire clean, stable, and reliable vital sign signals. Related systems and methods for vital sign monitoring are also provided herein. The sensor of various embodiments includes a multi-mode optical fiber, an LED light source, an LED driver, a receiver, and a single layer deformer structure. In various embodiments, the optical fiber and single layer deformer structure of the sensor are selected to meet specific parameters necessary to achieve a level of reliability and sensitivity needed to successfully monitor vital signs. In some embodiments, a specific sizing relationship exists between the optical fiber and the single layer deformer structure. In sonic embodiments, the sensor is configured to acquire ballistocardiograph waveforms.

Abstract: Systems and methods of monitoring posture and vital signs are disclosed. In some embodiments, the system includes a cushion on which a user can sit. The cushion includes a first optical fiber sensor, a second sensor, and a first computing device. The system may further include a second computing device communicatively coupled to the first computing device and configured to receive sensor data from the first computing device. One or both of the first and second computing devices may operate to combine a signal indicative of the movement of the user with a signal indicative of the direction of movement of the user to determine a posture of the user. The system may provide feedback based on the user's posture and recommend actions to improve posture. The system may further monitor the user's heart rate, respiration rate, or other vital signs.

Abstract: An intensity-based, micro-bending optical fiber sensor is disclosed herein, which is configured to acquire clean, stable, and reliable vital sign signals. Related systems and methods for vital sign monitoring are also provided herein. The sensor of various embodiments includes a multi-mode optical fiber, an LED light source, an LED driver, a receiver, and a single layer deformer structure. In various embodiments, the optical fiber and single layer deformer structure of the sensor are selected to meet specific parameters necessary to achieve a level of reliability and sensitivity needed to successfully monitor vital signs. In some embodiments, a specific sizing relationship exists between the optical fiber and the single layer deformer structure. In sonic embodiments, the sensor is configured to acquire ballistocardiograph waveforms.