Abstract: An integrated circuit device includes an interconnect layer, a memory structure, a third conductive feature, and a fourth conductive feature. The interconnect layer includes a first conductive feature and a second conductive feature. The memory structure is over and in contact with the first conductive feature. The memory structure includes at least a resistance switching element over the first conductive feature. The third conductive feature, including a first conductive line, is over and in contact with the second conductive feature. The fourth conductive feature is over and in contact with the memory structure. The fourth conductive feature includes a second conductive line, a top surface of the first conductive line is substantially level with a top surface of the second conductive line, and a bottom surface of the first conductive line is lower than a bottommost portion of a bottom surface of the second conductive line.

Abstract: A coordinate generation system, a coordinate generation method, a computer readable recording medium with stored program, and a non-transitory computer program product are provided. The coordinate generation system includes processing units and a neural network module. The processing units are configured to obtain four vertex coordinates of an image. The vertex coordinates include first components and second components. The processing unit is configured to perform the following steps: obtaining first vector based on the first components of the four vertex coordinates and repeatedly concatenating the first vector so as to obtain a first input; obtaining second vector based on the second components of the four vertex coordinates and repeatedly concatenating the second vector so as to obtain a second input; and obtaining first output coordinate components and second output coordinate components of output coordinates based on the first input, the second input, and parameters of the neural network module.

Abstract: The present invention discloses a meta-optics element comprising a substrate, a meta-optics structure and an anti-reflection structure. The meta-optics structure comprises multiple meta-optics units geometrically disposed on the substrate. The anti-reflection structure comprises multiple anti-reflection units corresponding to these meta-optics units and disposed on the surface of the corresponding meta-optics units. Besides, a manufacture method of meta-optics element is also disclosed.

Abstract: A sensor with a chamber comprises a base, a cavity body, a sensing element, and a porous gel material. The cavity body is disposed on the base and has a cavity wall and an inner space formed inside the cavity wall, the sensing element is disposed on the cavity wall, and the porous gel material is disposed between the base and the cavity body, the porous gel material has a porosity of not less than 80%, so that gas is capable of communicating between the inner space of the cavity body and an outside, thereby forming a passage for gas to enter and exit to balance a pressure in the sensor with the chamber, increase a support of the sensor with the chamber, and reduce the risk of conventional bonding between the sensing element and the base using die-bonding adhesive.

Abstract: A gas detection system for gynecological disease detection and a detection method using the same are provided. The gas detection system is configured to detect an analyte from a female vagina and includes: a main body, a sleeve, a detection module, a pump, and a control module. The main body includes a body portion and a head portion having an intake channel. The body portion includes a detection chamber and an exhaust channel. The detection module includes at least one sensor configured to detect at least one target of the analyte and produce at least one detection signal. The pump is communicated with the detection chamber and the exhaust channel. The control module includes a processing unit and a first communication unit. The processing unit receives the at least one detection signal and controls the first communication unit to send the at least one detection signal.

Abstract: A sensor with a chamber comprises a base, a cavity body, a sensing element, and a porous gel material. The cavity body is disposed on the base and has a cavity wall and an inner space formed inside the cavity wall, the sensing element is disposed on the cavity wall, and the porous gel material is disposed between the base and the cavity body, the porous gel material has a porosity of not less than 80%, so that gas is capable of communicating between the inner space of the cavity body and an outside, thereby forming a passage for gas to enter and exit to balance a pressure in the sensor with the chamber, increase a support of the sensor with the chamber, and reduce the risk of conventional bonding between the sensing element and the base using die-bonding adhesive.

Abstract: The present invention provides a pneumonia detection device for detecting an exhaled air of a patient to determine whether the lungs of the patient have been infected by at least one bacterial species. The device comprises a multi-gas sensing module, a temperature and humidity control module, and an operation control unit. The multi-gas sensing module comprises a gas sensor array reacting with a gas metabolized from the bacteria to generate a plurality of characteristic signals. The temperature and humidity control module controls and measures an operational condition of 45° C.-60° C. and humidity between 7% and 20% for the gas sensor array. The gas sensor array contacts with the exhaled air to generate a plurality of measurement signals. The operation control unit comparisons the measurement signals and the characteristic signals of different bacteria to generate a result determining whether the patient has contracted the bacteria.

Abstract: The present invention provides a wireless communication device and a subscriber identity module card in a wireless communication device. The subscriber identity module card comprises a flat plate carrier, a subscriber identity module circuit and a gas sensing chip. The flat plate carrier comprises a first surface where the subscriber identity module circuit is disposed, a second surface where the gas sensing chip is disposed, a through hole, and an electrical contact portion passing through the through hole and extending to reach the first surface and the second surface. The electrical contact portion is electrically connected to the subscriber identity module circuit and the gas sensing chip. The gas sensing chip is disposed on a portion of the subscriber identity module card where not occupied by the subscriber identity module circuit. Thus, the wireless communication device provides gas sensing function without additionally equipping with an external gas sensing element.

Abstract: A dry etching process for manufacturing a trench structure of a semiconductor apparatus, including the steps of: step 1, providing a semiconductor substrate, wherein the semiconductor substrate is provided with a patterned photoresist layer and placed in a reaction chamber; step 2, introducing a first etching gas into the reaction chamber to perform a first etching process to form a trench, wherein the first etching gas includes sulfur hexafluoride, oxygen, helium, nitrogen trifluoride, and a first organic silicide; step 3, introducing a second etching gas into the reaction chamber to perform a second etching process to further etch the trench, wherein the second etching gas includes sulfur hexafluoride, oxygen, helium, and a second organic silicide; and step 4, introducing a third etching gas into the reaction chamber to perform a third etching process, wherein the third etching gas includes hydrobromic acid, oxygen, and helium.

Abstract: The present invention provides a wireless communication device and a subscriber identity module card in a wireless communication device. The subscriber identity module card comprises a flat plate carrier, a subscriber identity module circuit and a gas sensing chip. The flat plate carrier comprises a first surface where the subscriber identity module circuit is disposed, a second surface where the gas sensing chip is disposed, a through hole, and an electrical contact portion passing through the through hole and extending to reach the first surface and the second surface. The electrical contact portion is electrically connected to the subscriber identity module circuit and the gas sensing chip. The gas sensing chip is disposed on a portion of the subscriber identity module card where not occupied by the subscriber identity module circuit. Thus, the wireless communication device provides gas sensing function without additionally equipping with an external gas sensing element.

Abstract: An electronic device includes a front bezel, a panel module, an image capturing module and a sliding cover assembly. The front bezel is disposed between the panel module and the image capturing module. The image capturing module is for capturing light passing through the panel module and entering an opening on the front bezel to generate an image information. The sliding cover assembly includes a covering component movably disposed between a front side of the front bezel and the panel module. The covering component is moveable relative to the front bezel for selectively covering the opening to prevent the light from entering into the opening so as to prevent the image capturing module from generating the image information or not covering the opening to allow the light to enter into the opening so as to allow the image capturing module to generate the image information.

Abstract: A gas sensor for a handheld device is assembled in a cavity of the handheld device. The gas sensor comprises a sensing chip, a circuit board and a gas channel. During operation, when a to-be-sensed gas is blown to a first sub-channel away from a gas inlet via a second sub-channel in the gas channel adjacent to the gas inlet, a gas pressure is weakened by the channel, so that the gas pressure of the first sub-channel is lower than the gas pressure of the second sub-channel. Therefore, dust and other tiny substances are prevented from entering the handheld device, and the damage to the sensing chip caused by the gas pressure during blowing can also be avoided.

Abstract: A method for manufacturing a gas detector by a micro-electrical-mechanical systems (MEMS) process. The method includes providing a MEMS wafer including a plurality of mutually adjacent units; forming a gas sensing material layer on the MEMS wafer; bonding a structure reinforcing layer and the MEMS wafer through anode bonding; providing an adhesive tape; performing a cutting process to form a gas detection unit; and adhering the gas detection unit on a substrate by the adhesive tape to form a gas detector. The structure reinforcing layer is capable of enhancing the strength of a device and preventing edge collapsing, and hence enhancing the overall yield rate and reducing costs.

Abstract: A method for manufacturing a microfluidic device includes following steps. A mold made of a glass material is provided. The mold has at least one hollow mold cavity and at least one blocking wall around the hollow mold cavity. The mold is disposed on a silicon substrate, which includes a formation surface corresponding to the hollow mold cavity and a microfluidic male mold protruding from the formation surface. Polydimethylsiloxane (PDMS) is poured into the hollow mold cavity and baked to harden the PDMS to form the microfluidic device. The microfluidic device has a microfluidic structure corresponding to the microfluidic male mold, and a height of a sidewall of the microfluidic device is between 3 mm and 30 mm. With the glass material of the mold, the microfluidic device having a sidewall height greater than 3 mm can be manufactured, preventing an insufficient suction force of a negative pressure.

Abstract: A method for manufacturing a gas detector by a micro-electrical-mechanical systems (MEMS) process. The method includes providing a MEMS wafer including a plurality of mutually adjacent units; forming a gas sensing material layer on the MEMS wafer; bonding a structure reinforcing layer and the MEMS wafer through anode bonding; providing an adhesive tape; performing a cutting process to form a gas detection unit; and adhering the gas detection unit on a substrate by the adhesive tape to form a gas detector. The structure reinforcing layer is capable of enhancing the strength of a device and preventing edge collapsing, and hence enhancing the overall yield rate and reducing costs.