Abstract: A system for detecting filament and needle breakage, including: an image acquisition module, an image processing module and a host computer detection module. The image acquisition module includes a light source, a camera and a lens. The image processing module includes a preprocessing submodule and a detection model. The host computer detection module includes a shutdown control-data interaction submodule of a warp knitting machine, a sensor control board, and a system operation interface. The image acquisition module captures a blanket knitting image at a knitting mechanism of the warp knitting machine. The image processing module pre-processes the blanket knitting image and detects filament and needle breakage. The host computer detection module controls a textile device according to detection results to generate an alarming information. A detection method implemented by the system is further provided.

Abstract: The present invention discloses a graphene cochlear implant electrode and a fabrication method thereof. The electrode comprises a tip portion, bendable portions, contact electrodes, an electrode carrier and wire electrodes, wherein the tip portion is disposed at forepart of the cochlear implant electrode, the electrode carrier wraps the wire electrodes and half wraps the contact electrodes connected to the wire electrodes one by one, and each bendable portion is an annular groove disposed on the electrode carrier; each contact electrode comprises an inner contact and an outer contact, when bending, the inner contact faces the modiolus while the outer contact faces away from the modiolus; and each wire electrode is wavy.

Abstract: The present invention discloses an MRI compatible magnet for a cochlear implant, comprising a base, an upper shell, a bracket, a magnet, needle rollers and a lower shell, wherein the upper shell and the lower shell form a closed space, and the magnet and the bracket are arranged in the closed space; the magnet is in an axisymmetric polygonal disk shape; the magnetic pole of the magnet is divided into two halves from the top view, one half is an N pole, and the other half is an S pole; the magnet is arranged in the bracket; the bracket is matched with the magnet in shape, and the bracket rotates with the magnet when the magnet rotates axially; a plurality of positioning slots are provided on the outer side face of the bracket; and , the needle rollers are accommodated in the positioning slots, and the needle rollers are cylindrical and can axially roll in the positioning slots without slipping off.

Abstract: Disclosed are a graphene oxide cochlear implant electrode and a manufacturing method thereof. The graphene oxide cochlear implant electrode includes an electrode tip, an electrode carrier, electrode contacts, a first positioning ring, a second positioning ring, a boosting portion, an electrode wire, a loop electrode, a loop electrode wire and a wire array, herein the electrode tip is arranged at a foremost portion of the cochlear implant electrode, the electrode carrier is silica gel grafted with a graphene oxide, the electrode carrier wraps the electrode wire and semi-wraps the electrode contacts connected to the electrode wire one by one, and the electrode carrier is slightly curved as a whole; and the electrode wire is connected to the electrode contacts one by one and forms a spiral shape through the first positioning ring, the second positioning ring and the boosting portion.

Abstract: Disclosed are a graphene oxide cochlear implant electrode and a manufacturing method thereof. The graphene oxide cochlear implant electrode includes an electrode tip, an electrode carrier, electrode contacts, a first positioning ring, a second positioning ring, a boosting portion, an electrode wire, a loop electrode, a loop electrode wire and a wire array, herein the electrode tip is arranged at a foremost portion of the cochlear implant electrode, the electrode carrier is silica gel grafted with a graphene oxide, the electrode carrier wraps the electrode wire and semi-wraps the electrode contacts connected to the electrode wire one by one, and the electrode carrier is slightly curved as a whole; and the electrode wire is connected to the electrode contacts one by one and forms a spiral shape through the first positioning ring, the second positioning ring and the boosting portion.

Abstract: The present invention discloses a graphene cochlear implant electrode and a fabrication method thereof. The electrode comprises a tip portion, bendable portions, contact electrodes, an electrode carrier and wire electrodes, wherein the tip portion is disposed at forepart of the cochlear implant electrode, the electrode carrier wraps the wire electrodes and half wraps the contact electrodes connected to the wire electrodes one by one, and each bendable portion is an annular groove disposed on the electrode carrier; each contact electrode comprises an inner contact and an outer contact, when bending, the inner contact faces the modulus while the outer contact faces away from the modulus; and each wire electrode is wavy.

Abstract: The present invention discloses a rapid neural response telemetry (NRT) circuit and system of a cochlear implant. The circuit comprises a stimulus generator, a signal amplifier, an analog-to-digital (A/D) converter and a calculated data memory. The stimulus generator zero charges in a nerve tissue before stimulus onset and offset, and the onset asynchrony of two continuous stimuli on the same electrode may be adjusted at will. The signal amplifier filters and amplifies nervous impulse signals that are evoked by electric stimuli and received by a collector electrode. The A/D converter can adjust the sampling frequency and start-up time, and is connected to the signal amplifier to perform A/D conversion on amplified analog signals. The calculated data memory is connected to the A/D converter to calculate and store the data undergoing A/D conversion.

Abstract: A programmable cochlear implant system utilizes multiple-resolution current sources and flexible data-encoding scheme for transcutaneous transmission. In certain embodiments, the number of current sources may be equal to or greater than 2, but equal or less than N?1, where N is the number of electrodes. The multi-resolution current source may introduce offset currents to achieve perceptually-based multiple resolutions with high resolution at low amplitudes and low resolution at high amplitudes. The flexible data-encoding scheme may allow arbitrary waveforms in terms of phase polarity, phase duration, pseudo-analog-waveform, while producing high-rate and high-temporal-precision stimulation. In one embodiment, a 2-current-source system may support simultaneous and non-simultaneous stimulation as well as monopolar, bipolar, pseudo-tripolar, and tripolar electrode configurations.

Abstract: A programmable cochlear implant system utilizes multiple-resolution current sources and flexible data-encoding scheme for transcutaneous transmission. In certain embodiments, the number of current sources may be equal to or greater than 2, but equal or less than N?1, where N is the number of electrodes. The multi-resolution current source may introduce offset currents to achieve perceptually-based multiple resolutions with high resolution at low amplitudes and low resolution at high amplitudes. The flexible data-encoding scheme may allow arbitrary waveforms in terms of phase polarity, phase duration, pseudo-analog-waveform, while producing high-rate and high-temporal-precision stimulation. In one embodiment, a 2-current-source system may support simultaneous and non-simultaneous stimulation as well as monopolar, bipolar, pseudo-tripolar, and tripolar electrode configurations.

Abstract: A programmable cochlear implant system utilizes multiple-resolution current sources and flexible data-encoding scheme for transcutaneous transmission. In certain embodiments, the number of current sources may be equal to or greater than 2, but equal or less than N?1, where N is the number of electrodes. The multi-resolution current source may introduce offset currents to achieve perceptually-based multiple resolutions with high resolution at low amplitudes and low resolution at high amplitudes. The flexible data-encoding scheme may allow arbitrary waveforms in terms of phase polarity, phase duration, pseudo-analog-waveform, while producing high-rate and high-temporal-precision stimulation. In one embodiment, a 2-current-source system may support simultaneous and non-simultaneous stimulation as well as monopolar, bipolar, pseudo-tripolar, and tripolar electrode configurations.