Abstract: Provided is a manufacturing method of a sensor including the following steps. A mold having a cavity is provided. At least one chip is disposed in the cavity. The chip has an active surface and a back surface opposite to each other. The active surface faces toward a bottom surface of the cavity. A polymer material is filled in the cavity to cover the back surface of the chip. A heat treatment is performed, such that the polymer material is solidified to form a polymer substrate. A mold release treatment is performed to isolate the polymer substrate from the cavity. A plurality of conductive lines are formed on a first surface of the polymer substrate. The conductive lines are electrically connected with the chip.

Abstract: The present invention provides a layout pattern of a static random access memory (SRAM). The layout pattern includes a first inverter and a second inverter constituting a latch circuit, wherein the latch circuit includes four transistors, a first access transistor (PG1) and a second access transistor (PG2) being electrically connected to the latch circuit, wherein the first access transistor is electrically connected to a first word line and a first bit line, and the second access transistor is electrically connected to a second word line and a second bit line, the first access transistor has a first gate length, the first access transistor has a second gate length, and the first gate length is different from the second gate length, and two read transistors series connected to each other, wherein one of the two read transistors is connected to the latch circuit.

Abstract: The invention relates to a conductive paste comprising from 30 to 97% by weight of electrically conductive particles, from 0 to 20% by weight of a glass fit, from 3 to 70% by weight of an organic medium and from 0.1 to 67% by weight of a silicone oil, each based on the total mass of the paste, wherein the silicone oil hasa boiling pointor a boiling rangein the range between 180° C. and 350° C. The invention further relates to a use of the conductive paste and a process for producing electrodes on a semiconductor substrate using the paste.

Abstract: Methods and apparatus for correcting quantization errors in signal reception based on estimated network loading including solutions for preserving cellular network performance in low noise, high interference environments. In one embodiment, a data channel is amplified with respect to other signals based on network load during periods of relatively low network utilization. Dynamic modification of the data channel's power level is configured to overcome quantization errors, rather than the true noise floor (which is insignificant in low noise environments). Such solutions provide both the fidelity necessary to enable high degrees of unwanted signaling rejection, while still preserving data channel quality.

Abstract: A layout pattern of a static random access memory, including a first inverter and a second inverter constituting a latch circuit. A first inner access transistor, a second inner access transistor, a first outer access transistor and a second outer access transistor are electrically connected to the latch circuit, wherein the first outer access transistor has a first gate length, the first inner access transistor has a second gate length, and the first gate length is different from the second gate length.

Abstract: A method for analyzing concentration of a cardiovascular disease (CVD) biomarker in a liquid sample includes: applying the liquid sample to a biosensor, the biosensor including a transistor having a drain, a source, and a gate terminal disposed between the gate and the source, and a reactive electrode spaced apart from the gate terminal of the transistor and having a receptor immobilized thereon for specific binding with the CVD biomarker, the liquid sample being in contact with the gate terminal and the reactive electrode; applying a voltage pulse between the reactive electrode and the source, the voltage pulse having a pulse width; monitoring a response current in response to the voltage pulse; and analyzing the response current.

Abstract: Embodiments of the present Invention provide antibody functionalized high electron mobility transistor (HEMT) devices for marine or freshwater pathogen sensing. In one embodiment, the marine pathogen can be Perkinsus marinus. A sensing unit can include a wireless transmitter fabricated on the HEMT. The sensing unit allows testing in areas without direct access to electrical outlets and can send the testing results to a central location using the wireless transmitter. According to embodiments, results of testing can be achieved within seconds.

Abstract: A multi-function ruler is provided with a rectangular, transparent body; at least one opening through a top and an underside of the body; and at least one row of a plurality of equally spaced markings printed along one side of the body. The at least one opening includes at least one directional sign, at least one curve, and at least one figure.

Abstract: A slot board structure for a shelf comprises a plurality of slot boards, two side plates, and a plurality of hanging arms. The slot boards are stacked one another from top to bottom. The two side plates are respectively connected with a left and right side of each slot board. Each side plate has a rear shielding plate portion, a connection plate portion, a front shielding plate portion, and a plurality of inverted L-shaped hook portions. Two side plates are respectively connected with the left and the right sides of each slot board so that one part of each L-shaped side plate may shield the front side of each slot board to prevent the connection among the slot boards from exposing. The quantity of the slot boards is different so as to adjust the volume of the slot board structure and further adapt to the shelf having different sizes.

Abstract: A method for measuring free radical comprises providing a sensor including a substrate and a conductive polymer layer, wherein the conductive polymer layer is configured on the substrate and made of conductive polymer; applying a liquid sample with free radical to the sensor so that the conductive polymer layer is covered with the liquid sample and the conductivity of the conductive polymer layer is lowered due to oxidation of the conductive polymer by free radical; and calculating the concentration of the free radical in the liquid sample based on the conductivity change rate of the conductive polymer before and after the liquid sample is applied to the conductive polymer. The present invention has advantages including low cost, small size, and ease of operation, which make it a good candidate for detecting hydroxyl radicals for oxidative stress studies.

Abstract: A method for analyzing concentration of an analyte in a liquid sample applied to a biosensor includes: applying a voltage pulse to the liquid sample applied to the biosensor, the voltage pulse having a pulse width of not greater than 10?3 second; monitoring a response current, which is produced in response to the voltage pulse, within the pulse width via electrodes of the biosensor; and analyzing the response current that is correlated to the concentration of the analyte in the liquid sample.

Abstract: In a ball movement state measuring system with a ball, a sensing module, a wireless communication module, a power supply and an induction coil, the speed, rotation speed, rotation axis and trace of the ball at first movement state are calculated based on first accelerated speed and first angular velocity of the ball at first movement state and first movement result is obtained by the processor. The speed, rotation speed, rotation axis and trace of the ball at second movement state are calculated based on speed and rotation axis of the ball at first movement state, second accelerated speed and environment parameter of the ball at second movement state and second movement result is obtained by the processor. The ball is forced by gravity, applied force and air resistance at first movement state, and the ball is forced by gravity, air resistance and centripetal force at second movement state.

Abstract: A semiconductor structure includes a SRAM cell having transistors defined by fins and metal gate stack structures. A transistor and a corresponding pick up cell are disposed in an extension direction of the fins. The transistor and the corresponding pick up cell have metal gate stack structures of the same type.

Abstract: Performing measurement of a first RAT while connected to a second RAT. The UE may initially communicate with a base station of the second RAT. While maintaining a connection to the base station of the first RAT, the UE may perform base station measurement of the first RAT (e.g., using a single radio of the UE). However, the measurement of the first RAT may be influenced by various factors, such as signal quality metrics of the second RAT. For example, if signal quality metrics are high for the second RAT, measurement of the first RAT may not be desirable, e.g., for battery life reasons.

Abstract: A user equipment and method performs an adaptive channel estimation. The method performed at a user equipment includes receiving physical downlink control channel (PDCCH) information for a subframe from a network, the subframe including reference symbols at predetermined times therein. If the PDCCH information does not include a downlink grant for the user equipment, a measured value of a network metric experienced by the user equipment is determined and compared to a threshold criteria. A first set of the reference symbols is used for channel estimation when the threshold value is satisfied and a second set of the reference symbols is used for channel estimation when the threshold is not satisfied, the first set of references symbols is a subset of the second set of the reference symbols. In another embodiment, a previously determined channel estimation at a previous subframe is used for the subframe when the threshold is satisfied.

Abstract: A communication system includes a plurality of communication devices, and a server. The communication devices share a phone number and respectively have an identification data. The server stores a state data corresponding to the phone number. The state data includes an allowable communication state corresponding to each of the identification data. The server allows one of the communication devices to communicate through the server according to the allowable communication state and disallows the other communication devices to communicate through the server. The allowed communication device transmits a command to the server to change the allowable communication state of the state data according to an operation of a user, that one of the disallowed communication devices is allowed to communicate through server instead, and the originally allowed communication device is disallowed to communicate instead.

Abstract: A viscosity measurement system, which is for measuring the viscosity of a fluid, comprises a transistor-type viscosity sensor, an electrical measurement unit, and a processing unit. The transistor-type viscosity sensor includes a semiconductor structure, a source terminal, and a drain terminal. The semiconductor structure includes a GaN layer and an AlGaN layer disposed on the GaN layer. The portion of the semiconductor structure that is between the source terminal and the drain terminal has a gate region, which has an exposed surface for being in contact with the fluid. The electrical measurement unit is in electrical connection with the source terminal and the drain terminal and for measuring an electronic signal of the semiconductor structure. The processing unit is coupled to the electrical measurement unit and for determining the viscosity of the fluid according to the electronic signal measured.

Abstract: Provided is a manufacturing method of a sensor including the following steps. A mold having a cavity is provided. At least one chip is disposed in the cavity. The chip has an active surface and a back surface opposite to each other. The active surface faces toward a bottom surface of the cavity. A polymer material is filled in the cavity to cover the back surface of the chip. A heat treatment is performed, such that the polymer material is solidified to form a polymer substrate. A mold release treatment is performed to isolate the polymer substrate from the cavity. A plurality of conductive lines are formed on a first surface of the polymer substrate. The conductive lines are electrically connected with the chip.

Abstract: A tissue identification method including a preparation step and a detection step is provided. The preparation step includes preparing a biosensor which includes a transistor and a response electrode. The response electrode is spaced apart from the transistor relative to a gate terminal of the transistor. The detection step includes disposing a biological tissue sample to be identified on the response electrode, applying a pulse voltage that has a tunable pulse width and a tunable pulse height to the response electrode, resulting in a voltage difference between the response electrode and the gate terminal of the transistor, and measuring and calculating a detection current which is generated from the transistor in the pulse width, so as to obtain a first sensing indicator. In addition, a biosensor for tissue identification is also provided.

Abstract: A layout pattern of a static random access memory, including a first inverter and a second inverter constituting a latch circuit. A first inner access transistor, a second inner access transistor, a first outer access transistor and a second outer access transistor are electrically connected to the latch circuit, wherein the first outer access transistor has a first gate length, the first inner access transistor has a second gate length, and the first gate length is different from the second gate length.