Abstract: A microphone includes a conducting vibrating diaphragm; a back plate opposed to the vibrating diaphragm and including a plurality of through holes; a first electrode formed in a middle of the back plate; a second electrode formed at an edge of the back plate; and a support portion located between the first electrode and the second electrode for supporting the vibrating diaphragm when the vibrating diaphragm is electrified. When the sound pressure is applied in the middle of the vibrating diaphragm and drives the vibrating diaphragm to deform, the middle of the vibrating diaphragm moves relative to the first electrode, and the edge of the vibrating diaphragm moves relative to the second electrode, at this time, the first electrode and the second electrode generate reversed electric signals.

Abstract: The present disclosure discloses a gesture recognition system. The gesture recognition system includes a processor configured to send a pulse signal and recognize corresponding hand gesture command according to an algorithm, an ultrasonic generator configured to receive the pulse signal sent by the processor and then send an ultrasonic wave, and a microphone including a signal pick-up unit configured to receive the ultrasonic wave reflected by a target object and generate a reflected signal and a signal processing unit configured to compare the reflected signal and the pulse signal so as to generate time data and frequency shift data, and then transmit the same to the processor. The present disclosure also provides a gesture recognition method. The gesture recognition system and the gesture recognition method using the system solve the problem of requirement on high-frequency sampling and data transmission, and thus high power consumption and large bandwidth occupation.

Abstract: An MEMS microphone is provided in the present disclosure. The MEMS microphone includes a protective structure comprising a housing and a PCB substrate covering the housing to form a receiving space, the housing is provided with a sound hole, an MEMS chip with a back cavity, received in the receiving space and fixed on the PCB substrate, the back cavity is communicated with the sound hole, and the MEMS chip comprises a first surface away from the PCB substrate and a second surface opposite to the first surface; and a waterproof part, bonded to the first surface of the MEMS chip.

Abstract: An MEMS microphone is provided in the present disclosure. The MEMS microphone includes a protective structure comprising a housing and a PCB substrate covering the housing to form a receiving space, the housing is provided with a sound hole, an MEMS chip with a back cavity, received in the receiving space and fixed on the PCB substrate, the back cavity is communicated with the sound hole, and the MEMS chip comprises a first surface away from the PCB substrate and a second surface opposite to the first surface; and a waterproof part, bonded to the first surface of the MEMS chip.

Abstract: A microphone includes a conducting vibrating diaphragm; a back plate opposed to the vibrating diaphragm and including a plurality of through holes; a first electrode formed in a middle of the back plate; a second electrode formed at an edge of the back plate; and a support portion located between the first electrode and the second electrode for supporting the vibrating diaphragm when the vibrating diaphragm is electrified. When the sound pressure is applied in the middle of the vibrating diaphragm and drives the vibrating diaphragm to deform, the middle of the vibrating diaphragm moves relative to the first electrode, and the edge of the vibrating diaphragm moves relative to the second electrode, at this time, the first electrode and the second electrode generate reversed electric signals.

Abstract: A MEMS microphone, includes a base with a back cavity and a capacitor system fixed to the base. The capacitor system includes a back plate above the base and a diaphragm opposite to the back plate for forming an insulated gap. The back plate includes a body part and multiple spaced fixation parts extending from the body part, and the diaphragm includes a vibrating part and a connecting part extending from the vibrating part. An orthographic projection of the body part of the back plate along a vibration direction of the diaphragm is completely located on the diaphragm; and at least a part of an orthographic projection of the fixation parts along the vibration direction is located on the diaphragm.

Abstract: The invention discloses a MEMS microphone, which includes a case with an accommodating cavity and an acoustic vent arranged on the case, a housing with an empty cavity as well as MEMS and ASIC chips with a back cavity are arranged inside the accommodating cavity. The housing is installed on the case, the MEMS chips are installed in the housing, the housing is arranged with a through hole connecting the empty cavity and the back cavity. The housing is also arranged with a vent hole. The MEMS microphone also includes a membrane flap arranged on the housing and used to close the vent hole. The membrane flap changes its shape under airflow effects and opens the vent hole. The MEMS microphone of this invention can avoid the diaphragm of the MEMS chips being damaged by airflow impact.

Abstract: A pressure sensing device is disclosed in the present disclosure. The pressure sensing device includes a bottom plate, a flexible shell and a MEMS pressure sensor. The flexible shell covers the bottom plate for forming a hermetical cavity, and the MEMS pressure sensor is accommodated in the hermetical cavity. Air in the hermetical cavity is compressed when the flexible shell is pressed, the MEMS pressure sensor is configured for detecting variation of an air pressure within the hermetical cavity when the flexible shell is pressed, and convert the variation of the air pressure into an electric signal.

Abstract: The present invention discloses a CT security inspection system for baggage. The CT security inspection system comprises a scanning passage through which a baggage enters and exits the CT security inspection system for baggage, an X-ray source provided at one side of the scanning passage, and, a gantry provided at an opposite side of the scanning passage, and on which a plurality of detector units are mounted. In each of the detector units, a vertex point of at least one detector unit is positioned in a detector unit distribution circle with its center at a center of the scanning passage, and the detector units are arranged successively. All the detector crystal receiving faces of the plurality of detector units are within a scope of radiating ray beams with their center at the target of the X-ray source.

Abstract: Disclosed is system, apparatus and method for centralized management of security inspection devices, which provide connection and communication between local security inspection devices and a remote control site according to bus communication scheme. The system comprises: a plurality of security inspection devices arranged on the spot; a remote control site arranged at a remote side; and a field bus network connecting the plurality of security inspection devices with the remote control site and transmitting signals between the plurality of security inspection devices and the remote control site according to bus communication scheme. With implementations of the present invention, correct and reliable centralized management of local security inspection devices from the remote control site can be achieved with less signal lines and simpler layout of the lines.

Abstract: The present disclosure provides a distributed amplifier, including: a drain transmission line; a gate transmission line; GFETs, in which sources of the graphene field-effect transistors are respectively grounded; gates of the graphene field-effect transistors respectively connected with a plurality of first shunt capacitors which are grounded; the gate transmission line is connected with a plurality of first nodes respectively between the gates of the graphene field-effect transistors and the plurality of first shunt capacitors, having a plurality of first inductors respectively between each two first nodes; drains of the graphene field-effect transistors respectively connected with a plurality of second shunt capacitors which are grounded; the drain transmission line is connected with a plurality of second nodes respectively between the drains of the graphene field-effect transistors and the plurality of second shunt capacitors, having a plurality of second inductors respectively between each two second node

Abstract: This disclosure provides a clustering storage method and apparatus. The method includes: storing to-be-stored first data row by row into a local memory in a database system; determining a first sorting column, where the first sorting column is used to sort data that has been cached in the local memory; sorting second data according to the first sorting column if the second data that has been cached in the local memory meets a preset condition, where the second data is data, which has been cached into the local memory, in the first data; and storing the sorted second data in a clustering manner into a storage medium in the database system.

Abstract: A CT apparatus without a gantry. The CT apparatus includes a scanning passage; a stationary X-ray source arranged around the scanning passage and including a plurality of ray emission focal spots; and a plurality of stationary detector modules arranged around the scanning passage and disposed opposite the X-ray source. At least some of the plurality of detector modules may be arranged substantially in an L shape, a semicircular shape, a U shape, an arc shape, a parabolic shape, or a curve shape when viewed in a plane intersecting the scanning passage. The invention ensures that the stationary gantry type CT system has a small size, and a high data identification accuracy.

Abstract: A pressure sensing device is disclosed in the present disclosure. The pressure sensing device includes a bottom plate, a flexible shell and a MEMS pressure sensor. The flexible shell covers the bottom plate for forming a hermetical cavity, and the MEMS pressure sensor is accommodated in the hermetical cavity. Air in the hermetical cavity is compressed when the flexible shell is pressed, the MEMS pressure sensor is configured for detecting variation of an air pressure within the hermetical cavity when the flexible shell is pressed, and convert the variation of the air pressure into an electric signal.

Abstract: Disclosed is an encoder and encoding method for slip ring. The encoder includes: an encoding belt that is fixed to a slip ring and has a plurality of holes regularly arranged on the encoding belt; at least one pair of first sensors provided on one side of the encoding belt, wherein the first sensors of each pair generate a first sense signal and a first redundant sense signal respectively based on light emitted from the other side of the encoding belt and passing through the plurality of holes, when the encoding belt rotates with the slip ring; and at least one signal combiner connected to the at least one pair of the first sensors, and configured to combine the first sense signal and the first redundant sense signal to obtain a combined sense signal as a first encoded signal.

Abstract: A photoelectric switch for detection of an object. The photoelectric switch comprises: a light transmitter unit comprising plural light transmitters configured to emit plural light signals; a light receiver unit comprising plural optical fiber receivers in one-to-one correspondence with the plural light transmitters and configured to receive the plural light signals and to merge plural light signals, wherein an object detection area is defined between the plural light transmitters and the plural optical fiber receivers; a photoelectric conversion unit connected to the optical fiber receivers and configured to perform photoelectric conversions on the merged light signals outputted by the optical fiber receivers so as to generate an electric signal; and a control and processing unit connected to both the light transmitter unit and the photoelectric conversion unit, and configured to control and process the light signals and/or the electric signal.

Abstract: The present disclosure discloses a scanning imaging system, comprising a transportation apparatus, a first imaging system, and a second imaging system. A distance between a ray beam from a first ray generator of the first imaging system and a ray beam from a second ray generator of the second imaging system in the transportation direction is roughly L. A controller is configured to acquire, based on a count value of the encoding counter module, a correspondence relationship between data in a position of the inspected object in the transportation direction which is collected by the first imaging system and data in the position of the inspected object in the transportation direction which is collected by the second imaging system, wherein a difference between a count value of the encoder corresponding to the data in the position which is collected by the first imaging system and a count value of the encoder corresponding to the data in the position which is collected by the second imaging system is roughly L/D.

Abstract: A stationary CT apparatus and a method of controlling the same. The stationary CT apparatus includes: a scanning passage; a stationary carbon nanotube X-ray source arranged around the scanning passage and comprising a plurality of ray emission focal spots; and a plurality of stationary detector modules arranged around the scanning passage and disposed opposite the X-ray source. At least some of the plurality of detector modules are arranged in a substantially L shape or a substantially ? shape when viewed in a plane intersecting the scanning passage. Reconstruction of the CT apparatus without a rotary gantry is achieved and special substances in an object under inspection is identified by optimizing design of the carbon nanotube X-ray source and the detector device. The invention ensures that the stationary gantry type CT system has a small size and a high accuracy and is particularly suitable for safety inspection of baggage.

Abstract: The present disclosure provides a distributed amplifier, including: a drain transmission line; a gate transmission line; GFETs, in which sources of the graphene field-effect transistors are respectively grounded; gates of the graphene field-effect transistors respectively connected with a plurality of first shunt capacitors which are grounded; the gate transmission line is connected with a plurality of first nodes respectively between the gates of the graphene field-effect transistors and the plurality of first shunt capacitors, having a plurality of first inductors respectively between each two first nodes; drains of the graphene field-effect transistors respectively connected with a plurality of second shunt capacitors which are grounded; the drain transmission line is connected with a plurality of second nodes respectively between the drains of the graphene field-effect transistors and the plurality of second shunt capacitors, having a plurality of second inductors respectively between each two second node

Abstract: This invention relates to an X-ray goods inspection apparatus, and in particular to a goods inspection apparatus using distributed X-ray source.