Three-dimensionally tailored pouch structure for men's briefs

A three-dimensionally tailored pouch structure for men's briefs includes a first receiving space for receiving a wearer's penis and a second receiving space for receiving the wearer's scrotum. A vent is formed between the first and second receiving spaces for communicating the two receiving spaces with an outer space. By providing the first and second receiving spaces on the pouch structure, the wearer's penis and scrotum can be isolated from each other. Also the vent allows convection to occur between ambient air and the first and second receiving spaces, so that the two receiving spaces of the pouch structure are always dry and comfortable in touch.

THREE-DIMENSIONALLY TAILORED POUCH STRUCTURE FOR MEN'S BRIEFS

A three-dimensionally tailored pouch structure for men's briefs includes a first receiving space for receiving a wearer's penis and a second receiving space for receiving the wearer's scrotum. A vent is formed between the first and the second receiving space for communicating the two receiving spaces with an outer space. By providing the first and the second receiving space on the pouch structure, the wearer's penis and scrotum can be isolated from each other. And, the vent allows convection to occur between ambient air and the first and second receiving spaces, so that the two receiving spaces of the pouch structure are always dry and comfortable in touch. 1. A three-dimensionally tailored pouch structure for men's briefs , comprising:a connecting opening for connecting to a crotch front opening on men's briefs and being communicable with an inner side of the men's briefs;a first receiving space being communicable with the connecting opening and adapted to receive a wearer's penis for completely enclosing a front end of the penis therein; anda second receiving space being communicable with the connecting opening and located adjacent to the first receiving space for receiving the wearer's scrotum therein.2. The three-dimensionally tailored pouch structure for men's briefs as claimed in claim 1 ,wherein the pouch structure is formed by sewing up a single piece of fabric, which includes an encircling strip portion and a bendable panel portion located below the encircling strip portion, and the bendable panel portion having a folding line that forms a borderline between the encircling strip portion and the bendable panel portion.3. The three-dimensionally tailored pouch structure for men's briefs as claimed in claim 2 ,wherein the encircling strip portion includes a sewing edge, which forms the connecting opening, a first lateral edge having two ends connected to an end of the sewing edge and of the folding line, and a second lateral edge having two ends connected to ...

TOUCH DISPLAY PANEL WITH INTEGRAL FINGERPRINT SENSOR AND ELECTRONIC DEVICE USING SAME

A touch display panel which includes an integral fingerprint recognition portion also comprises a central processor, a switch module, and a main touch portion. The fingerprint recognition portion comprises fingerprint recognition electrodes connected to the central processor. The main touch portion comprises touch electrodes to sense touches. At least one touch electrode is electrically connected to one fingerprint recognition electrode through the switch module, and the switch module is controlled by the processor to cycle through connected or disconnected states between the touch electrode and the fingerprint recognition electrode. 1. A touch display panel , comprising:a central processor;a switch module;a fingerprint recognition portion, wherein the fingerprint recognition portion is configured to sense a fingerprint signal, the fingerprint recognition portion comprises a plurality of fingerprint recognition electrodes; anda main touch portion, wherein the main touch portion is configured to sense a touch position, and the main touch portion comprises a plurality of touch electrodes, and at least one of the plurality of touch electrodes is electrically connected to one of the plurality of fingerprint recognition electrodes through the switch module;wherein the switch module is electrically connected to the central processor, the central processor further controls the switch module to establish an electrical connection between the at least one of the plurality of touch electrodes and the at least one of the plurality of fingerprint recognition electrodes or disconnect the at least one of the plurality of touch electrodes from the at least one of the plurality of fingerprint recognition electrodes.2. The touch display panel of claim 1 , wherein the switch module comprises a plurality of switching elements claim 1 , each of the plurality of switching elements comprises two thin film transistors (TFTs) connected to each other in parallel claim 1 , each of the TFTs ...

Shift register and touch display apparatus thereof

A shift register driving a touch display device generates shifted pulse signals shifted by a specified phase. The shift register includes unit circuits connected in multiple stages. Each unit circuit includes an output terminal, an input transistor, an output transistor, and a pull-up transistor. The input transistor is controlled by a first control signal and outputs a high-level voltage to a first node based on the value of a trigger signal. The output transistor outputs the shifted pulse signal, which is synchronous with a clock control signal, based on the value of the high-level voltage of the first node. A blank period is inserted between the Nth unit circuit and the (N+1)th unit circuit. After the blank period, the pull-up transistor clamps the voltage of the output terminal of the (N+1)th unit circuit at a high-level voltage.

MICRO LED DISPLAY PANEL

A micro LED display panel includes a first metal layer, a micro LED layer on the first metal layer, and a transparent conductive layer on a side of the micro LED layer opposite from the first metal layer. The micro LED layer includes a plurality of micro LEDs spaced apart from each other. The first metal layer includes a plurality of first metal units spaced apart from each other. The plurality of first metal units serve as anodes or cathodes of the plurality of micro LEDs. The transparent conductive layer includes a plurality of transparent conductive units spaced apart from each other. The plurality of transparent conductive units serve as anodes or cathodes of the plurality of micro LEDs and are multiplexed as touch electrodes. The micro LED display panel of the present disclosure has both a display function and a touch function. 1. A micro LED display panel , comprising:a first metal layer, the first metal layer comprising a plurality of first metal units spaced apart from each other;a micro LED layer on the first metal layer, the micro LED layer comprising a plurality of micro LEDs spaced apart from each other, the plurality of first metal units serving as anodes or cathodes of the plurality of micro LEDs; anda transparent conductive layer on a side of the micro LED layer opposite from the first metal layer;wherein the transparent conductive layer comprises a plurality of transparent conductive units spaced apart from each other, the plurality of transparent conductive units serve as anodes or cathodes of the plurality of micro LEDs and the plurality of transparent conductive units are multiplexed as touch electrodes.2. The micro LED display panel of claim 1 , further comprising a control circuit layer claim 1 , and the plurality of first metal units are electrically coupled to the control circuit layer.3. The micro LED display panel of claim 2 , wherein each of the plurality of transparent conductive units is independently electrically coupled to the control ...

TWIN-MODE TOUCH DISPLAY PANEL

A touch display panel operating in alternating touch-sensing modes includes a first substrate and a second substrate facing the first substrate, and with first electrodes on the first substrate and second electrodes on the second substrate. The touch display panel can work in a self-capacitance mode and a mutual-capacitance mode in sensing touch operations. The mutual-capacitance mode is implemented by the first electrodes and the second electrodes working together and the self-capacitance mode is implemented by the first electrodes alone. 1. A touch display panel , comprising:a first substrate;a second substrate facing the first substrate;a plurality of first electrodes on the first substrate, the plurality of first electrodes being spaced apart from each other; anda plurality of second electrodes on the second substrate, the plurality of second electrodes being spaced apart from each other;wherein the touch display panel is capable of working in a self-capacitance mode and a mutual-capacitance mode both for sensing touch operation, by switching between the self-capacitance mode and the mutual-capacitance mode; the self-capacitance mode is implemented by the plurality of first electrodes; the mutual-capacitance mode is implemented by the plurality of first electrodes and the plurality of second electrodes.2. The touch display device of claim 1 , wherein the first substrate is a thin film transistor array substrate; the second substrate is a color filter substrate; and a liquid crystal layer is between the first substrate and the second substrate.3. The touch display device of claim 2 , wherein the plurality of first electrodes is located on a side of the first substrate adjacent to the liquid crystal layer.4. The touch display device of claim 2 , wherein the plurality of second electrodes is located on a side of the second substrate away from the liquid crystal layer.5. The touch display device of claim 1 , wherein the plurality of first electrodes are arranged in ...

Touch display panel

A touch display panel includes a color filter substrate, a thin film transistor substrate, a liquid crystal layer between the color filter substrate and the thin film transistor substrate, a touch sensing structure, and a force sensing structure. The touch display panel defines a display area and a border area surrounding the display area. The touch sensing structure is in the display area, and the force sensing structure is in the border area. The force sensing structure includes a plurality of first force sensing electrodes and a second force sensing electrode stacked on and electrically insulated from the first force sensing electrodes. The first force sensing electrodes and the second force sensing electrode cooperatively form a capacitive force sensing structure.

TOUCH DISPLAY PANEL

A touch display device includes a display module and a sensing module on the display module. The sensing module includes a first electrode layer on the display module, a second electrode layer facing the first electrode layer, and a dielectric layer between the first electrode layer and the second electrode layer. The second electrode layer includes a plurality of electrodes. The electrodes functions as electrodes of the touch display device for sensing a touch position. The electrodes, the first electrode layer, and the dielectric layer cooperatively form capacitors for sensing a touch force. 1. A touch display device comprising:a display module;a sensing module on the display module, the sensing module comprising:a first electrode layer on the display module;a second electrode layer facing the first electrode layer; anda dielectric layer between the first electrode layer and the second electrode layer;wherein the second electrode layer comprises a plurality of electrodes; the plurality of electrodes functions as electrodes of the touch display device for sensing a touch position; the plurality of electrodes, the first electrode layer, and the dielectric layer cooperatively form capacitors for sensing a touch force.2. The touch display device of claim 1 , wherein the plurality of electrodes are spaced apart from each other and arranged in a matrix of rows and columns; each row of the electrodes is arranged along an X axis direction; and each column of the electrodes is arranged along a Y axis direction.3. The touch display device of claim 2 , wherein each of the plurality of electrodes is electrically coupled to a trace; each trace is connected to a corner of a corresponding electrode; the electrodes in each column of the electrodes have area sizes gradually decrease along the Y axis direction; the traces of the plurality of electrodes are parallel to each other.4. The touch display device of claim 3 , wherein the traces of each column of the electrodes are at a ...

TOUCH DISPLAY DEVICE

A touch display device able to receive touches and sense the touch forces includes a color filter substrate, a thin film transistor substrate, a liquid crystal layer, and an electrically-conductive frame on a side of the display panel away from the color filter substrate. First electrodes are formed on a surface of the color filter substrate adjacent to the liquid crystal layer and second electrodes are formed on a surface of a thin film transistor substrate adjacent to the liquid crystal layer. The first electrodes and the second electrodes cooperatively form a first capacitor for sensing touch force, and the second electrodes and the electrically-conductive frame cooperatively form a second capacitor for sensing touch force. 1. A touch display device comprising:a color filter substrate;a thin film transistor substrate facing the color filter substrate;a liquid crystal layer between the color filter substrate and the thin film transistor substrate; andan electrically-conductive frame on a side of the thin film transistor substrate away from the color filter substrate;wherein a plurality of first electrodes are formed on a surface of the color filter substrate adjacent to the liquid crystal layer; a plurality of second electrodes are formed on a surface of the thin film transistor substrate adjacent to the liquid crystal layer; the plurality of first electrodes and the plurality of second electrodes cooperatively form a first capacitor for sensing a touch force, and the plurality of second electrodes and the electrically-conductive frame cooperatively form a second capacitor for sensing the touch force; the plurality of second electrodes functions as electrodes of the touch display device for sensing a touch position.2. The touch display device of claim 1 , wherein an air gap is formed between the thin film transistor substrate and the electrically-conductive frame.3122. The touch display device of claim 1 , wherein a first distance is formed between the plurality ...

IN-CELL TOUCH DISPLAY APPARATUS

An in-cell touch display apparatus includes a color filter structure, a thin film transistor (TFT) array structure, a liquid crystal layer between the color filter structure and the TFT array structure, and a driving and detection unit. The color filter structure comprises a touch electrode layer. The TFT array structure comprises a conductive layer. The touch electrode layer comprises a plurality of touch electrodes arranged in a matrix and a plurality of pressure sensing electrodes arranged in a matrix. The touch electrodes and the pressure sensing electrodes are located on a same layer. The conductive layer comprises a plurality of conductive portions. The touch electrodes sense a touch position, and the pressure sensing electrodes and the conductive portions cooperate with each other to sense a touch pressure. 1. An in-cell touch display apparatus with a plurality of pixel units , the in-cell touch display apparatus comprising:a color filter structure;a thin film transistor (TFT) array structure;a liquid crystal layer between the color filter structure and the TFT array structure; anda driving and detection unit;wherein the color filter structure comprises a first substrate and a touch electrode layer, the touch electrode layer is disposed on a the first substrate adjacent to the liquid crystal layer; the TFT array structure comprises a second substrate and a conductive layer, the conductive layer is disposed on the second substrate adjacent to the liquid crystal layer; the driving and detection unit are electrically connected to the touch electrode layer and the conductive layer; the touch electrode layer comprises a plurality of touch electrodes arranged in a matrix and a plurality of pressure sensing electrodes arranged in a matrix; the touch electrodes and the pressure sensing electrodes are on a same layer; the conductive layer comprises a plurality of conductive portions; the touch electrodes sense a position of a touch operation applied on the in-cell ...

Touch display panel

A touch display device includes a color filter substrate, and a thin film transistor substrate facing the color filter substrate. The thin film transistor substrate includes a common electrode layer. A force sensing electrode layer is formed on the color filter substrate. The common electrode layer includes a plurality of common electrodes. The common electrodes function as electrodes of the touch display device for sensing a touch position. The common electrodes and the force sensing electrode layer cooperatively form capacitors for sensing a touch force, their capacitance varying as a result of the distance between them being reduced.

TOUCH DISPLAY APPARATUS

A touch display apparatus a display unit and a touch unit. The display unit displays images and the touch unit which is overlapped on the display unit can sense independently a touch action applied on the touch unit and also the pressure applied in such touch. The touch display apparatus virtually simultaneously operates under a display period and a touch period in one frame for improving accuracy of determining the aspects of a touch function. 1. A touch display apparatus comprising:a display unit displaying images;a touch unit, the touch unit overlapping with the display unit, and for sensing a touch action applied on the touch unit; and a first conductive layer overlapping with the display unit;', 'an insulating layer overlapped on and in direct contact with the first conductive layer, and deforming based on the force of a touch action applied to the touch display apparatus; and', 'a second conductive layer overlapped on and direct contacted with the insulating layer;, 'wherein the touch unit comprisingwherein the first conductive layer is adjacent to the display unit, the second conductive layer is located on a surface of the insulating layer opposite from the display unit; the first conductive layer comprises a plurality of first electrodes and a plurality of second electrodes; the first electrodes and the second electrodes are arranged in a matrix; each first electrodes cooperates with one of the second electrodes to sense a position of the touch action; the first conductive layer and the second conductive layer cooperates with each other to sense a pressure of the touch action.2. The touch display apparatus of claim 1 , wherein during one frame claim 1 , the display unit display operates under a display period for displaying images and at the same time the touch unit operates under a touch period for sensing the pressure and the position of the touch action applied on the touch display apparatus.3. The touch display apparatus of claim 2 , wherein the touch ...

SELF-LUMINESCENCE DISPLAY APPARATUS WITH TOUCH FUNCTION

A self-luminescence display apparatus includes a display panel having a plurality of conductive layers and a supporting frame. One of the conductive layers cooperates with the supporting frame to form a plurality of force sensing capacitors. When a touch action is applied, the display panel deforms according to pressure applied, which cause the capacitances of the force sensing capacitors to alter, which corresponds to a place where the touch operation applied on. 1. A self-luminescence display apparatus comprising:an organic light emitting diode (OLED) display panel having a plurality of conductive layers and supported by a supporting framewherein one of the conductive layers of the display panel cooperate with the supporting frame to form force sensing capacitors; when a touch action is applied on the self-luminescence display apparatus, a capacitance of the force sensing capacitors alters, and the self-luminescence display apparatus senses the force based on capacitance differences of the force sensing capacitors, which corresponds to a place where the touch action is applied.2. The self-luminescence display apparatus of claim 1 , wherein the conductive layers comprises a first electrode layer claim 1 , a second electrode layer claim 1 , a thin film transistor (TFT) array layer between the first substrate and the second substrate claim 1 , a hole injection layer claim 1 , a hole transport layer claim 1 , an emission layer claim 1 , and an electric injection layer; the first electrode layer claim 1 , the second electrode layer claim 1 , the hole injection layer claim 1 , the hole transport layer claim 1 , the emission layer claim 1 , and the electric injection layer cooperate with each other to form a plurality of OLEDs; the hole injection layer claim 1 , the hole transport layer claim 1 , the emission layer claim 1 , and the electric injection layer are sequentially stacked between the first electrode layer and the second electrode layer.3. The self-luminescence ...

OLED TOUCH DISPLAY PANEL

An OLED touch display device includes a first electrode layer, a second electrode layer facing the first electrode layer, a light-emitting layer between the first electrode layer and the second electrode, and a third electrode layer on a side of the first electrode layer. The first electrode layer functions as a cathode of the light-emitting layer, and the second electrode layer functions as an anode of the light-emitting layer. The first electrode layer and the third electrode layer cooperatively form a capacitive force sensing element. The first electrode layer also functions as touch sensing electrode. 2121. The OLED touch display device of claim 1 , wherein the first electrode layer includes a plurality of first electrodes spaced apart from each other; wherein the plurality of first electrodes are arranged in rows and columns; and wherein each of the rows of the first electrodes extends along a first direction D and each of the columns of the first electrodes extends along a second direction D; wherein the first direction D is perpendicular to the second direction.3. The OLED touch display device of claim 2 , wherein the plurality of first electrodes function as cathode of the light-emitting layer claim 2 , touch sensing electrodes claim 2 , and force sensing electrodes by a time-division manner.4. The OLED touch display device of claim 3 , wherein the light-emitting layer comprises a plurality of light-emitting units spaced apart from each other; wherein the second electrode layer comprises a plurality of pixel electrodes spaced apart from each other; wherein each of the plurality of light-emitting units corresponds to one of the plurality of pixel electrodes; wherein the OLED touch display panel defines a plurality of pixel units arranged in rows and columns; wherein each of the plurality of pixel units comprises at least one of the plurality of pixel electrodes and at least one of the plurality of light-emitting units corresponding to the at least one of the ...

Shift register module and display driving circuit thereof

A display driving circuit for driving pixel units comprises a time controller, a first driving circuit, and a second driving circuit. The first driving circuit comprises a plurality of shift registers, and supplies phase-shifted scan signals. The shift registers are connected in cascade. Each shift register receives two clock signals from the time controller. Each shift register is a bidirectional shift register. Each shift register includes a pull-up transistor, a pull-down transistor, and a pull-down unit. The pull-down unit controls the pull-down transistor to turn on after the shift register being reset to prevent the shift register outputting an error signal.

IN-CELL TOUCH DISPLAY PANEL

A TFT substrate comprising a first conductive layer, a first semiconductor layer, a second semiconductor layer, a second conductive layer formed over the first semiconductor layer, a first transparent layer, a third conductive layer, and a second transparent layer. The TFT substrate further comprises a plurality of touch sensor units. 1. A thin film transistor (TFT) substrate comprising:a first conductive layer, the first conductive layer patterned to form a gate electrode;a first semiconductor layer formed over the first conductive layer, the first semiconductor layer insulated from the first conductive layer;a second semiconductor layer formed over the first conductive layer and insulated from the first conductive layer, the second semiconductor layer coplanar with the first semiconductor layer;a second conductive layer formed over the first semiconductor layer and the second semiconductor layer, and patterned to form a first drain electrode, a second drain electrode, and a first source electrode, wherein the first drain electrode, the second drain electrode, and the first source electrode are all positioned on the gate electrode;a third conductive layer formed over the first transparent layer, the third conductive layer patterned to form a second source electrode positioned on the gate electrode; andwherein the TFT substrate further comprises a plurality of touch sensor units positioned in a matrix; each of the touch sensor units comprises a plurality of first wires and a plurality of second wires crossed with the first wires to form a metal mesh pattern; the touch sensor units are spaced at an interval from each other; a minimum grid area of each of the touch sensor units is defined by the crossed conductive wire and the transparent conductive wire which corresponds to two sub-pixel electrodes and a TFT structure; the TFT structure simultaneously drives the two sub-pixels; the TFT structure comprises two TFTs; one of the two TFTs is comprised of the gate ...

CIRCUIT AND METHOD FOR USE IN A FIRST DISPLAY DEVICE TO FACILITATE COMMUNICATION WITH A SECOND DISPLAY DEVICE, AND DISPLAY COMMUNICATION SYSTEM

A circuit for use in a first display device to facilitate communication with a second display device is provided. The first display device and the second display device each include a connector compliant with a digital display interface standard. The circuit includes a digital display interface circuit and a control unit. The digital display interface circuit is used for transmission or receiving of video data according to the digital display interface standard, the digital display interface circuit for being connected to the connector of the first display device. The control unit is configured to transmit at least one first communication signal through at least one first pin of the connector of the first display device to communicate with the second display device, wherein the at least one first communication signal is non-standard with respect to the digital display interface standard. 1. A circuit for use in a first display device to facilitate communication with a second display device , the first display device and the second display device each including a corresponding connector compliant with a digital display interface standard , the circuit comprising:a digital display interface circuit for transmission or receiving of video data according to the digital display interface standard, the digital display interface circuit for being connected to the connector of the first display device; anda control unit being configured to transmit at least one first communication signal through at least one first pin of the connector of the first display device to communicate with the second display device through a cable compliant with the digital display interface standard to be connected between the connectors of the first display device and the second display device, wherein the at least one first communication signal is non-standard with respect to the digital display interface standard.2. The circuit according to claim 1 , wherein the digital display interface ...

X-RAY DEVICE

An X-ray device is provided, which includes a flexible substrate, a driver integrated circuit, and a scintillator layer. The flexible substrate includes an array portion and an extension portion. The driver integrated circuit is disposed on the flexible substrate. The scintillator layer is disposed on the flexible substrate. 1. An X-ray device , comprising:a flexible substrate comprising an array portion and an extension portion;a driver integrated circuit disposed on the flexible substrate; anda scintillator layer disposed on the flexible substrate.2. The X-ray device according to claim 1 , further comprising:a carrier disposed on the extension portion, wherein the carrier and the driver integrated circuit are disposed on different sides of the flexible substrate.3. The X-ray device according to claim 1 , further comprising:a supporting plate disposed on the array portion, wherein the supporting plate and the scintillator layer are disposed on different sides of the flexible substrate.4. The X-ray device according to claim 3 , wherein the supporting plate at least partially overlap the scintillator layer in a top view direction.5. The X-ray device according to claim 3 , wherein the extension portion is bent to have a part that is disposed on a different side of the supporting plate from the array portion.6. The X-ray device according to claim 5 , wherein the driver integrated circuit comprises a first driver integrated circuit disposed on the part and a second driver integrated circuit disposed on the array portion.7. The X-ray device according to claim 1 , further comprising:a plurality of element modules disposed on the extension portion.8. The X-ray device according to claim 7 , wherein the driver integrated circuit comprises a first driver integrated circuit disposed on the extension portion and a second driver integrated circuit disposed on the array portion claim 7 , and wirings electrically connected to the second driver integrated circuit and the plurality ...

APPARATUS FOR IDENTIFYING MORPHOLOGY

An apparatus for identifying morphology comprises a substrate, a driving circuit, a readout circuit and an identifying circuit. The substrate comprises temperature sensors each comprising a sensing transistor. The driving circuit selects at least one of the transistors as a target sensing transistor, and outputs a driving signal to the target sensing transistor to heat the target sensing transistor in a heating period. The target sensing transistor senses a temperature change to generate a sensing signal in a sensing period after the heating period. The readout circuit reads the sensing signal, and the identifying circuit identifies the morphology according to the sensing signal. 1. An apparatus for identifying morphology , comprising:a first substrate, comprising a plurality of temperature sensors each comprising a sensing transistor;a driving circuit for selecting at least one of the sensing transistors as a target sensing transistor, and outputting a driving signal to the target sensing transistor to heat the target sensing transistor in a heating period, wherein the target sensing transistor senses a temperature change to generate a sensing signal in a sensing period after the heating period;a readout circuit for reading the sensing signal; andan identifying circuit for identifying the morphology according to the sensing signal.2. The apparatus according to claim 1 , wherein the sensing transistor is a metal-oxide-semiconductor field-effect-transistor (MOSFET).3. The apparatus according to claim 1 , wherein the sensing transistor is a bipolar junction transistor (BJT).4. The apparatus according to claim 1 , wherein the temperature sensor further comprises a resistor connected to the sensing transistor.5. The apparatus according to claim 1 , wherein the temperature sensor further comprises a function circuit connected to the sensing transistor.6. The apparatus according to claim 5 , wherein the function circuit is selected from a group consisting of an amplifier ...

Men's Underpants

Men's underpants (), made primarily of a single kind of cloth (). Said cloth comprises a pouch body () and a front band body () and a rear band body () extending out from the top of the pouch body (). Said men's underpants () also comprise a ring-shaped waistband (), which passes through the front band body () and the rear band body () to form a ring. Wearing the men's underpants () frees the user of unnecessary constriction and friction and enables the skin and pores to breath freely, thereby providing a high degree of comfort. 1. A pair of men's underpants being made of a single piece of cloth and comprising a pouch body , and a front band body and a rear band body extending from the top of the pouch body.2. The pair of men's underpants as claimed in further comprising a ring-shaped waistband inserting through the front and rear band bodies claim 1 , and each of the front and rear band bodies being provided at least one connecting portion for connecting to the ring-shaped waistband.3. The pair of men's underpants as claimed in claim 2 , wherein the connecting portion is a loop and hook fastener.4. The pair of men's underpants as claimed in claim 1 , wherein the pouch body is a penetrating cylindrical structure.5. The pair of men's underpants as claimed in claim 4 , wherein the pouch body tapers from a middle section adjacent to the top end thereof toward a top end and a bottom end of the cylindrical structure claim 4 , respectively.6. The pair of men's underpants as claimed in claim 2 , wherein the ring-shaped waistband is an elongated belt.7. The pair of men's underpants as claimed in claim 6 , wherein the connecting portion is formed at a free end of each of the front and rear band bodies claim 6 , and is ring-shaped for allowing the ring-shaped waistband to insert through.8. The pair of men's underpants as claimed in claim 6 , wherein the ring-shaped waistband is provided two loop and hook fasteners capable of being fastened to each other.9. The pair of men's ...

METHOD FOR DRIVING DISPLAY WITH PXEL UNITS IN ONE GROUP ARRANGED IN A SLANTED FORMATION

A method for driving a high-frequency display applied in a display apparatus with a border of reduced size selects one horizontal scan line for scanning during a selecting period. The signals of the selected horizontal scan line and two following horizontal lines adjacent to the selected horizontal scan line are made effective during a first sub-period. The signals of the selected horizontal scan line and a following horizontal scan line adjacent to the selected horizontal scan line are made effective during a second sub-period following. The signals of the selected horizontal scan line are made effective during a third sub-period following the second. 1. A diving method for driving a display apparatus , the display apparatus comprising a plurality of horizontal scan lines in a display region , and a plurality of data lines; in one frame time , a plurality of display periods and a plurality of touch periods are defined; each of the display periods comprises a plurality of selecting period; each of the selecting periods comprises a first sub-period , a second sub-period and a third sub-period in that order; the method comprising:selecting one of the plurality of horizontal scan lines for scanning;controlling signals of the selected horizontal scan line and two following horizontal lines adjacent to the selected horizontal scan line to be effective during the first sub-period;controlling the signals of the selected horizontal scan line and a following horizontal scan line adjacent to the selected horizontal scan line to be effective during the second sub-period;controlling the signal of the selected horizontal scan line to be effective during the third sub-period.2. The driving method of claim 1 , wherein the display apparatus comprises a plurality of pixel units arranged in a matrix; a plurality of pixel group are defined;each pixel group comprises at least three pixel units; the pixel units in a same pixel group are arranged on different columns along the first ...

HUMAN-COMPUTER INTERACTIVE REHABILITATION SYSTEM

The present invention provides a human-computer interactive rehabilitation system, which can automatically calculate rehabilitation strength suitable for the patient, so that it is not necessary to manually evaluate and adjust the parameter settings in human-computer interactive rehabilitation system when different patients use it. At the same time, the human-machine interactive rehabilitation system and the hospital end can track the rehabilitation status and intervene through the data platform at any time. The platform establishes a cloud community feedback and encouragement mechanism, and immediately transmits the rehabilitation results to the designated barriers of the patients, provides patient encouragement feedback, and strengthens the community interaction and linkage in the medical relationship. 1. A rehabilitation system for stroke sequelae , comprising:a visual device for providing a guide screen to a patient;a limb sensor worn on a limb of the patient to sense a motion of the limb to generate a sensing signal; andan information processing unit which establishes wireless communication with the visual device and the limb sensor, and comprises an input signal processing module, a rehabilitation operation weight processing module, and a content feedback presentation module;wherein, the content feedback presentation module transmits the guidance screen to the visual device, and the input signal processing module receives the sensing signal from the limb sensor and transmits the sensing signal to the rehabilitation operation weight processing module, and then the rehabilitation operation weight processing module estimates the current hand motion of the patient according to the sensing signal, and derives various actions of the patient to determine a recovery degree of stroke sequelae of the patient's limb, and the rehabilitation operation weight processing module simultaneously parameterizes the sensing signal into a range of values as the patient's current ...

Tft substrate and touch display panel using same

A TFT substrate defines a display area and a non-display area surrounding the display area. The TFT substrate includes a substrate and a conductive layer on the substrate. The conductive layer includes a plurality of touch driving electrodes, a plurality of touch sensing electrodes, and a plurality of common electrodes. The touch sensing electrodes are arranged in rows along a first direction and in columns along a second direction. Each touch driving electrode and each common electrode extend as strips along the first direction, the touch driving electrodes and the common electrodes are arranged in one column along the second direction. One common electrode and one row of the touch sensing electrodes are arranged at each side of each touch driving electrode along the second direction. The TFT substrate further includes a plurality of sensing lines.

TFT SUBSTRATE AND TOUCH DISPLAY PANEL USING SAME

A TFT substrate for a touch display panel of reduced thickness defines a display area and a surrounding non-display area. The TFT substrate includes a first conductive layer on the substrate and a second conductive layer on the first conductive layer. In the display area, the first conductive layer includes data lines and the second conductive layer includes common electrodes. Each common electrode extends as a strip along a first direction. Each data line extends along a second direction. The first direction intersects the second direction. Each data line crosses the common electrodes. Each data line functions as a touch driving electrode and each common electrode functions as a touch sensing electrode. 1. A TFT substrate defining a display area and a non-display area surrounding the display area , the TFT substrate comprising:a substrate;a first conductive layer on the substrate, the first conductive layer comprising a plurality of data lines in the display area; anda second conductive layer on the first conductive layer and insulated from the first conductive layer, the second conductive layer comprising a plurality of common electrodes in the display area;wherein each of the plurality of common electrodes extends as a strip along a first direction; each of the plurality of data lines extends along a second direction; the first direction intersect the second direction; each of the plurality of data lines crosses the plurality of common electrodes; each of the plurality of data lines functions as a touch driving electrode; each of the plurality of common electrodes functions as a touch sensing electrode.2. The TFT substrate according to claim 1 , further comprising a insulating material layer on the second conductive layer and a third conductive layer on the insulating material layer claim 1 , wherein the third conductive layer comprises a plurality of connecting wires in the display area; the insulating material layer defines a plurality of via holes extending ...

Photo responsive material and optical device

An optical device is provided, which includes a first transparent substrate, a second transparent substrate, and a liquid-crystal material disposed between the first transparent substrate and the second transparent substrate. The liquid-crystal material includes a photo responsive material with a chemical structure of: wherein A 1 is A 2 and A 3 are independently X is halogen. R is H, C 1-12 alkyl group, or C 1-12 alkoxy group. R′ is C 1-12 alkyl group.

Chiral catalyst and heterogeneous chiral catalyst comprising the same

A chiral catalyst represented by formula (II) is provided. In formula (II), Y independently includes hydrogen, fluorine, trifluoromethyl, isopropyl, tert-butyl, C m H 2m+1 or OC m H 2m+1 , wherein m=1-10 and n=1-10. A heterogeneous chiral catalyst is also provided. The heterogeneous chiral catalyst includes the chiral catalyst represented by formula (II), and a substrate connected to the chiral catalyst.

Chiral catalyst and heterogeneous chiral catalyst comprising the same

A chiral catalyst represented by formula (I) is provided. In formula (I), Z═Z 1 or Z 2 , and the combination of Z 1 and Z 2 in formula (I) includes Y independently includes hydrogen, fluorine, trifluoromethyl, isopropyl, tert-butyl, C m H 2m+1 or OC m H 2m+1 , m=1-10, and n=1-10. A heterogeneous chiral catalyst including the chiral catalyst is also provided.

Touch display panel and method for driving touch display panel

A display panel able to receive full fingerprint impressions in a display area together with command touches, in addition to showing images, includes a substrate, scan lines, data lines, touch scan lines, touch lines, sub-pixels, and fingerprint sensing units. A method for driving such multifunctional touch display panel is also provided.

THIN FILM TRANSISTOR SUBSTRATE AND IN-CELL TOUCH DISPLAY PANEL USING SAME

The present disclosure provides a thin film transistor (TFT) substrate. The TFT substrate includes a first metal layer, a second metal layer, a first transparent layer, a third metal layer, and a second transparent layer. The first metal layer includes at least one gate electrode. The second metal layer is insulated to the first metal layer and includes at least one source electrode and at least one drain electrode. The first transparent layer is insulated to the first metal layer and the second metal layer. The first transparent layer includes at least one common electrode layer. The third metal layer includes a plurality of metal wires electrically connected to the common electrode layer. The second transparent layer includes a plurality of transparent conductive wires electrically connected to the drain electrode. The metal wires and the transparent conductive wires form a touch sensing structure configured to detect touch operations. 1. A thin film transistor (TFT) substrate comprising:a first metal layer comprising at least one gate electrode;a second metal layer disposed over the first metal layer and insulated from the first metal layer, and the second metal layer comprises at least one source electrode and at least one drain electrode;a first transparent layer disposed over the second metal layer and insulated from the first metal layer and the second metal layer, and the first transparent layer comprises at least one common electrode layer;a third metal layer disposed over the first transparent layer and comprising a plurality of metal wires, each of the plurality of metal wires electrically connected to the common electrode layer; anda second transparent layer disposed over the third metal layer and comprising a plurality of transparent conductive wires, each of the plurality of transparent conductive wires electrically connected to the drain electrode,wherein the metal wires and the transparent conductive wires form a touch sensing structure configured to ...

MICRO LED TOUCH PANEL DISPLAY

A micro LED touch panel display includes the functions of a touch screen and micro LEDs. The touch panel display further includes a plurality of photodiodes. The photodiodes are configured to detect positions of touches by sensing variations of light intensity when a fingertip is pressed against the panel. The disclosure integrates touch technology into the micro LED touch panel display. 1. A micro LED touch panel display , comprising:a plurality of micro LEDs, wherein each micro LED comprises a first anode and a first cathode, each micro LED emits light when a voltage of the first anode is greater than a voltage of the first cathode; anda plurality of photodiodes, wherein each photodiode comprises a second anode and a second cathode, each anode and cathode having a voltage depending on variations in the light intensity received from the micro LEDS by the photodiode; a touch position is detected when the photodiodes detects a voltage of the second anode of the photodiode is less than a voltage of the second cathode of the photodiode.2. The micro LED touch panel display of claim 1 , wherein the micro LED touch panel display defines a plurality of pixel units claim 1 , each pixel unit comprises a photodiode and at least three micro LEDs claim 1 , each micro LED emitting light of a different color.3. The micro LED touch panel display of claim 2 , wherein each pixel unit comprises one red-light emitting LED emitting red light claim 2 , one green-light emitting LED emitting green light claim 2 , and one blue-light emitting LED emitting blue light.4. The micro LED touch panel display of claim 3 , wherein the red-light emitting LED claim 3 , the green-light emitting LED claim 3 , the blue-light emitting LED claim 3 , and the photodiode in each pixel unit are arranged in a 2×2 matrix.5. The micro LED touch panel display of claim 3 , wherein the red-light emitting LED claim 3 , the green-light emitting LED claim 3 , the blue-light emitting LED claim 3 , and the photodiode in ...

METHOD FOR MANUFACTURING DISPLAY DEVICE

A method for manufacturing a display device is disclosed, the method at least includes the following step: Firstly, a temporary substrate is provided, a hydrogen containing structure is formed on the temporary substrate, a polymer film is formed on the hydrogen containing structure, and a display element is formed on the polymer film. Afterwards, a laser beam process is performed, to focus a laser beam on the hydrogen containing structure, and the temporary substrate is then removed. 1. A method for manufacturing a display device , comprising:providing a temporary substrate;forming a hydrogen containing structure on the temporary substrate;forming a polymer film on the hydrogen containing structure, wherein the polymer film contacts the hydrogen containing structure directly;forming a display element on the polymer film;focusing a laser beam on the hydrogen containing structure; andremoving the temporary substrate and the hydrogen containing structure, wherein the hydrogen containing structure is separated from the polymer film.2. The method for manufacturing the display device according to claim 1 , wherein the hydrogen containing structure comprises an amorphous silicon film.3. The method for manufacturing the display device according to claim 2 , wherein the amorphous silicon film is removed in the step of removing the temporary substrate.4. The method for manufacturing the display device according to claim 2 , wherein a thickness of the amorphous silicon film is greater than or equal to 50 nm and less than or equal to 100 nm.5. The method for manufacturing the display device according to claim 2 , wherein the hydrogen containing structure further comprises a silicon nitride film disposed between the polymer film and the amorphous silicon film.6. The method for manufacturing the display device according to claim 5 , wherein the hydrogen containing structure is removed in the step of removing the temporary substrate.7. The method for manufacturing the display ...

Embedded touch-screen display panel

An embedded touch-screen display panel includes a first substrate and a second substrate sandwiching a driving circuit disposed on the second substrate. The second substrate also carries a touch electrode layer and a first selecting circuit. The driving circuit generates signals of touches and driving signals, and includes a plurality of touch detecting pins and a plurality of controlling pins. The touch electrode layer includes a plurality of touch electrodes. At least two touch electrodes are electrically connected to one touch detecting pin via the first selecting circuit. A touch signal is transmitted between the two touch electrodes and the touch detecting pin. The controlling pin generates signals to the first selecting circuit to establish or cut off electrical connections between the touch detecting pins and the touch electrodes.

EMBEDDED TOUCH DISPLAY PANEL

An embedded touch display panel includes a number of touch sensing electrodes arranged in a touch sensing layer of the embedded touch display panel. The number of touch sensing electrodes is positioned in a display area of the touch display panel and includes a number of central touch sensing electrodes arranged in a central portion of the display area and a number of peripheral touch sensing electrodes arranged in a peripheral portion of the display area. The peripheral display area surrounds the central display area, and the number of peripheral touch sensing electrodes is smaller in size than the number of central touch sensing electrodes. 1. An embedded touch display panel comprising:a touch sensing layer; and a plurality of central touch sensing electrodes arranged in a central portion of a display area of the embedded touch display panel; and', 'a plurality of peripheral touch sensing electrodes arranged in a peripheral portion of the display area of the embedded touch display panel, the peripheral portion surrounding the central portion, and the plurality of peripheral touch sensing electrodes being smaller in size than the plurality of central touch sensing electrodes., 'a plurality of touch sensing electrodes arranged in the touch sensing layer of the embedded touch display panel, the plurality of touch sensing electrodes comprising2. The embedded touch display panel as in comprising a driving chip positioned in a non-display area of the embedded touch display panel and electrically coupled to the plurality of touch sensing electrodes.3. The embedded touch display panel as in claim 2 , wherein:the embedded touch display panel comprises a first substrate, a second substrate, and a liquid crystal layer, the liquid crystal layer located between the first substrate and the second substrate; andthe touch sensing layer is located in the second substrate.4. The embedded touch display panel as in claim 3 , wherein:the plurality of central touch sensing electrodes ...

In-cell touch display apparatus

An in-cell touch display apparatus includes a substrate structure, a display driving integrated chip (IC), and a plurality of touch sensor units arranged in a matrix. Each of the touch sensor units includes a plurality of connecting lines of difference lengths and a plurality of compensating portions corresponding to the connecting lines in a one-to-one relationship. Each of the connecting lines establishes an electrical connection between the touch sensor unit and the display driving IC. The compensating portions are electrically connected to the display driving IC. The connecting lines and the compensating portions receive a common voltage from the display driving IC during the display period. A sum of the lengths of the connecting line and the compensating portion is constant throughout the plurality of connecting lines so as to compensate for different capacitances of the connecting lines.

SELF-LUMINESCENCE DISPLAY APPARATUS WITH TOUCH FUNCTION

A self-luminescence display apparatus capable of detecting pressure of touches applied by a user, the apparatus includes a display panel having a plurality of conductive layers and a supporting frame. One of the conductive layers cooperates with the supporting frame to form a plurality of force sensing capacitors. When a touch is applied, the display panel deforms according to pressure applied, which cause the capacitances of the force sensing capacitors to alter. The change in capacitance value, corresponding to a position where the touch operation is applied, can be calculated. 1. A self-luminescence display apparatus comprising:an organic light emitting diode (OLED) display panel having a plurality of conductive layers and supported by a supporting framewherein one of the conductive layers of the display panel cooperate with the supporting frame to form force sensing capacitors; when a touch action is applied on the self-luminescence display apparatus, a capacitance of the force sensing capacitors alters, and the self-luminescence display apparatus senses the force based on capacitance differences of the force sensing capacitors, which corresponds to a position where the touch action is applied.2. The self-luminescence display apparatus of claim 1 , wherein the conductive layers further comprises a first conductive layer; the first conductive layer cooperates with the supporting frame to form the force sensing capacitor.3. The self-luminescence display apparatus of claim 2 , wherein the first conductive layer is between the first substrate and the TFT array layer.4. The self-luminescence display apparatus of claim 2 , wherein the first conductive layer is between the first substrate and the supporting frame.5. The self-luminescence display apparatus of claim 2 , wherein the first conductive layer is between the second substrate and the second electrode layer.6. The self-luminescence display apparatus of claim 2 , wherein the conductive layers comprises a first ...

DISPLAY APPARATUS AND DRIVING METHOD THEREOF

A display apparatus with a border of reduced size includes pixel units arranged in a matrix. Each pixel unit includes a driving transistor. The display apparatus defines a display region and a non-display region. The display region includes horizontal scan lines and data lines. The horizontal scan lines are parallel with each along a first direction, and the data lines are parallel with each other along a second direction. A pixel group contains three pixels and these pixel units are arranged on different columns along the first direction, and in different rows along the second direction. The driving transistors of these pixel units are electrically connected to one data line through connection lines. 1. A display apparatus comprising:a plurality of pixel units arranged in a matrix, each of the pixel units comprises a driving transistor;a plurality of horizontal scan lines in a display region configured to extend along a first direction; anda plurality of data lines in the display region, and configured to extend along a second direction perpendicular to the first direction; andwherein a plurality of pixel group are defined; each pixel group comprises at least three pixel units; the pixel units in a same pixel group are arranged on different columns along the first direction, and further arranged on different rows along the second direction, the driving transistors of the pixel units in the same pixel group are electrically connected to a same data line through connection lines.2. The display apparatus of claim 1 , wherein the display region further comprises a plurality of vertical scan lines along the second direction; the vertical scan lines are patterned by a metal layer different from a metal layer patterned to form the horizontal scan lines claim 1 , and are electrically connected to the horizontal scan lines respectively through a corresponding first via hole for transmitting scan signals to the horizontal scan lines.3. The display apparatus of claim 1 , ...

THIN FILM TRANSISTOR ARRAY SUBSTRATE AND TOUCH DISPLAY PANEL USING SAME

A thin film transistor array substrate in a touch display panel having reinforced common voltage uniformity on sub-electrodes therein includes a common electrode layer, a driving circuit, a controlling switch, a plurality of first lines, at least one second line, and at least one third line. The common electrode layer includes the spaced sub-electrodes. Each sub-electrode uses a first line electrically connect to the driving circuit and the controlling switch. The at least one second line is electrically connected to the driving circuit and the controlling switch, and when the controlling switch is turned on, the second line is electrically connected to the first lines, the driving circuit thus applying a common voltage to the sub-electrodes. A touch display panel using the thin film transistor array substrate is also provided. 1. A thin film transistor array substrate , comprising:a substrate;a common electrode layer on the substrate, the common electrode layer comprising a plurality of sub-electrodes spaced apart from each other;a driving circuit on the substrate, the driving circuit configured to apply voltages to the plurality of sub-electrodes;a controlling switch on the substrate;a plurality of first lines, each sub-electrode electrically connected to the driving circuit and the controlling switch by at least one of the first lines; andat least one second line, the at least one second line electrically connected to the driving circuit and the controlling switch, wherein when the controlling switch is turned on, the at least one second line is electrically connected to the first lines, and the driving circuit applies a common voltage to each sub-electrode.2. The thin film transistor array substrate of claim 1 , wherein when the controlling switch is turned off claim 1 , the at least one second line is not electrically connected to the first lines claim 1 , and the driving circuit applies a touch driving voltage to each sub-electrode.3. The thin film transistor ...

Array substrate as extended fingerprint sensor, touch-display panel, and touch-display device using same

A fingerprint-sensing array on a substrate includes the substrate, scan lines, data lines, readout lines, sub-pixels, and multiple fingerprint recognition units. Areas between adjacent scan lines and adjacent data lines define one sub-pixel with pixel electrode and a first transistor. Of the first transistor, drain electrode connects to the pixel electrode, source electrode connects to one data line and gate electrode connects to one scan line. Thus some of the sub-pixels contain fingerprint recognition units, these being a photodiode electrically connected to one readout line. The readout line passes signals generated by the photodiode to achieve fingerprint recognition function. A display panel using the array on the substrate and a display device using the display panel are also provided.

TOUCH DISPLAY PANEL

A touch display device includes a touch display module. The touch display module includes a TFT substrate, a color filtering substrate, and a liquid crystal layer encapsulated between the TFT substrate and the color filtering substrate. A first electrode layer is formed on a surface of the color filtering substrate facing the TFT substrate. A second electrode layer is formed on a surface of the TFT substrate facing the color filtering substrate. The touch display device further includes at least one supporting element on a side of the touch display module. The supporting element is elastic and configured for elastically resisting against the touch display module. 1. A touch display device comprising:a touch display module comprising:a TFT substrate;a color filtering substrate; anda liquid crystal layer between the TFT substrate and the color filtering substrate;wherein a first electrode layer is formed on a surface of the color filtering substrate facing the TFT substrate; a second electrode layer is formed on a surface of the TFT substrate facing the color filtering substrate;wherein the touch display device further comprises at least one supporting element elastically resisting against the touch display module from a side of the TFT substrate opposite to the color filtering substrate; the at least one supporting element is elastic.2. The touch display device of claim 1 , wherein:the first electrode layer comprises a plurality of conducting lines intersecting with each other to form a mesh;a plurality of through holes is defined in the first electrode layer;the first electrode layer comprises a plurality of nodes; andeach of the plurality of nodes is formed where two conducting lines intersect with each other.3. The touch display device of claim 2 , wherein the second electrode layer comprises a plurality of touch sensing electrodes spaced apart from each other; the plurality of touch sensing electrodes forms a self capacitor structure configured for sensing touch ...

Scrotum pocket structure for men's underpants

A scrotum pocket structure for men's underpants which comprises a first chamber provided for holding man's penis and a second chamber provided for holding man's scrotum, which can separate the penis and scrotum from each other, so as to keep the underpants dry and further enhance wearing comfort.

Micro LED display panel

A micro LED display panel includes a first metal layer, a micro LED layer on the first metal layer, and a transparent conductive layer on a side of the micro LED layer opposite from the first metal layer. The micro LED layer includes a plurality of micro LEDs spaced apart from each other. The first metal layer includes a plurality of first metal units spaced apart from each other. The plurality of first metal units serve as anodes or cathodes of the plurality of micro LEDs. The transparent conductive layer includes a plurality of transparent conductive units spaced apart from each other. The plurality of transparent conductive units serve as anodes or cathodes of the plurality of micro LEDs and are multiplexed as touch electrodes. The micro LED display panel of the present disclosure has both a display function and a touch function.

Thin film transistor substrate and in-cell touch display panel using same

The present disclosure provides a thin film transistor (TFT) substrate. The TFT substrate includes a first metal layer, a second metal layer, a first transparent layer, a third metal layer, and a second transparent layer. The first metal layer includes at least one gate electrode. The second metal layer is insulated to the first metal layer and includes at least one source electrode and at least one drain electrode. The first transparent layer is insulated to the first metal layer and the second metal layer. The first transparent layer includes at least one common electrode layer. The third metal layer includes a plurality of metal wires electrically connected to the common electrode layer. The second transparent layer includes a plurality of transparent conductive wires electrically connected to the drain electrode. The metal wires and the transparent conductive wires form a touch sensing structure configured to detect touch operations.

Scrotum bag structure for man's underpants

本發明係為一種男用內褲的囊袋結構，其主要針對習知具有囊袋的男用內褲穿著後，男性的陰莖及陰囊仍保持接觸的容置在該囊袋內，造成不舒適感受所進行的發明，本發明的囊袋結構具有一供男性陰莖容置的第一容室、及一供男性陰囊容置的第二容室，因此，當男性穿著本發明時，本發明得以將男性的陰莖與陰囊確實隔離，達到穿著內褲後能保有乾爽舒適的效果。

Three-dimensionally tailored pouch structure for men's briefs

Circuit and method for use in a first display device to facilitate communication with a second display device, and display communication system

A circuit for use in a first display device to facilitate communication with a second display device is provided. The first display device and the second display device each include a connector compliant with a digital display interface standard. The circuit includes a digital display interface circuit and a control unit. The digital display interface circuit is used for transmission or receiving of video data according to the digital display interface standard, the digital display interface circuit for being connected to the connector of the first display device. The control unit is configured to transmit at least one first communication signal through at least one first pin of the connector of the first display device to communicate with the second display device, wherein the at least one first communication signal is non-standard with respect to the digital display interface standard.

Photo responsive material and optical device

An optical device is provided, which includes a first transparent substrate, a second transparent substrate, and a liquid-crystal material disposed between the first transparent substrate and the second transparent substrate. The liquid-crystal material includes a photo responsive material with a chemical structure of: wherein A 1 is A 2 and A 3 are independently X is halogen. R is H, C 1-12 alkyl group, or C 1-12 alkoxy group. R′ is C 1-12 alkyl group.

Semiconductor structure

A semiconductor structure includes an insulator, a semiconductor fin, a gate stack, a gate contact, a source/drain material, and a source/drain contact structure. The semiconductor fin protrudes from the insulator. The gate stack is disposed on the semiconductor fin and the insulator. The gate contact is disposed on and electrically connected to the gate stack. The source/drain material is disposed on the semiconductor fin. The source/drain contact structure is disposed on and electrically connected to the source/drain material. The semiconductor fin extends along a first direction, the gate stack extends along a second direction different from the first direction. An offset S in the second direction between the gate contact and the source/drain contact structure satisfies: 0<S≤(W/2+D/2), wherein W is a width of the semiconductor fin, and D is a dimension of the gate contact.

微電腦自動餵食及溫度控制器

一種微電腦自動餵食及溫度控制器，包括一溫度感測器、一加熱器、一餵食器以及一微電腦，溫度感測器用於感測一飼養箱內的溫度，加熱器用於對飼養箱內加熱，餵食器將飼料投入飼養箱中，微電腦依溫度感測器所測得飼養箱內的溫度，來控制加熱器進行加熱，使飼養箱內的溫度保持一預設值，並且控制餵食器進行投食。

コアシェル型量子ドットの調製装置および調製方法

【課題】合成の安定性を向上させ、調製時間を短縮するために、高効率の物質移動および熱移動を達成し得るコアシェル型量子ドットの調製装置を提供する。【解決手段】コアシェル型量子ドットの調製装置は、コア多段供給部品、コア反応部品、シェル供給部品およびシェル反応部品を含む。コア多段供給部品は、異なる反応溶液の供給ラインを含み、反応溶液の１つは、多段供給によって供給ラインを通して連続流路に輸送されるため、異なる反応物のモル比は、所定の比に維持される。コア反応部品は、コア多段供給部品と結合し、異なる反応溶液を反応させてコア構造を形成する。シェル反応部品は、コア反応部品の後の連続流路に結合され、シェル供給部品から供給されるシェルの反応溶液と連続流路からのコア構造とを受け取り、各コア構造の表面にシェル構造を形成する。【選択図】図１

Method of manufacturing detection panel

Disclosed is a method for manufacturing a detection panel, which includes the following steps. A first flexible board is provided, and the first flexible board has a circuit layer. A second flexible board is provided, the first flexible board is fixed on the second flexible board, and the first flexible board is disposed between the circuit layer and the second flexible board. A carrier board is provided, the carrier board is fixed on the second flexible board, and the second flexible board is disposed between the carrier board and the first flexible board. A scintillator is formed on the circuit layer. The carrier board is detached from the second flexible board. The first flexible board and the second flexible board are cut to form the detection panel.

X-ray device and manufacturing method thereof

An X-ray device, including a sensor panel and a flexible scintillator structure disposed on the sensor panel, is provided. A manufacturing method of the X-ray device is also provided.

Manufacturing method of x-ray device

An X-ray device, including a sensor panel and a flexible scintillator structure disposed on the sensor panel, is provided. A manufacturing method of the X-ray device is also provided.

Manufacturing method of X-ray device

An X-ray device, including a sensor panel and a flexible scintillator structure disposed on the sensor panel, is provided. A manufacturing method of the X-ray device is also provided.

Three-dimensionally tailored pouch structure for men's briefs

A three-dimensionally tailored pouch structure (31) for men's briefs (10) includes a first receiving space (21) for receiving a wearer's penis and a second receiving space (22) for receiving the wearer's scrotum. A vent is formed between the first and the second receiving space for communicating the two receiving spaces with an outer space. By providing the first and the second receiving space on the pouch structure, the wearer's penis and scrotum can be isolated from each other. And, the vent allows convection to occur between ambient air and the first and second receiving spaces, so that the two receiving spaces of the pouch structure are always dry and comfortable in touch.

X-ray device

An X-ray device is provided, which includes a flexible substrate, a driver integrated circuit, and a scintillator layer. The flexible substrate includes an array portion and an extension portion. The driver integrated circuit is disposed on the flexible substrate. The scintillator layer is disposed on the flexible substrate.

Ｘ線装置およびその製造方法

【課題】歩留まりの向上またはコストの削減に役立つＸ線装置およびその製造方法を提供する。【解決手段】センサパネル１０と可撓性シンチレータ構造１２を含むＸ線装置１は、センサパネル１０の上に可撓性シンチレータ構造１２が配置される。Ｘ線装置１の製造方法は、キャリアボードを準備し、可撓性シンチレータ構造１２をキャリアボードの上に配置し、キャリアボードを取り外し、可撓性シンチレータ構造１２をセンサパネル１０の上に配置する。【選択図】図１

X-ray device and manufacturing method thereof

An X-ray device, including a sensor panel and a flexible scintillator structure disposed on the sensor panel, is provided. A manufacturing method of the X-ray device is also provided.

Electronic device

An electronic device, including a sensing substrate, a scintillator layer, and an adjustable reflective layer, is provided. The scintillator layer is disposed on the sensing substrate. The adjustable reflective layer is disposed on the sensing substrate and includes a first electrode, a second electrode, and an electrophoretic layer. The first electrode is disposed on the scintillator layer. The second electrode is disposed on the first electrode. The electrophoretic layer is disposed between the first electrode and the second electrode. The second electrode surrounds the scintillator layer.

X-ray device

Zoom lens and method for manufacturing the same

A zoom lens is provided, which includes an electrode pattern on a substrate, and a liquid-crystal material on the electrode pattern. The electrode pattern includes a plurality of concentric ring electrodes surrounding an innermost electrode. Each of the concentric ring electrodes has an opening. A first trace extends from a first electrode out of an outermost concentric ring electrode to the innermost electrode. The first trace has greater resistance than the concentric ring electrodes and the innermost electrode. A second trace connecting the innermost electrode and a second electrode out of the outermost concentric ring electrode through the openings. The liquid-crystal material includes a liquid-crystal compound with a chemical structure of wherein R is C 4-10 alkyl group, n=1 or 2, and each of X is independently H or F.