Abstract: A photomask structure including a first layout pattern and a second layout pattern is provided. The second layout pattern is located on one side of the first layout pattern. The first layout pattern and the second layout pattern are separated from each other. The first layout pattern has a first edge and a second edge opposite to each other. The second layout pattern has a third edge and a fourth edge opposite to each other. The third edge of the second layout pattern is adjacent to the first edge of the first layout pattern. The second layout pattern includes a first extension portion exceeding an end of the first layout pattern. The first extension portion includes a first protruding portion protruding from the third edge of the second layout pattern. The first protruding portion exceeds the first edge of the first layout pattern.

Abstract: A semiconductor device includes a semiconductor substrate having a first region and a second region, insulators, gate stacks, and first and second S/Ds. The first and second regions respectively includes at least one first semiconductor fin and at least one second semiconductor fin. A width of a middle portion of the first semiconductor fin is equal to widths of end portions of the first semiconductor fin. A width of a middle portion of the second semiconductor fin is smaller than widths of end portions of the second semiconductor fin. The insulators are disposed on the semiconductor substrate. The first and second semiconductor fins are sandwiched by the insulators. The gate stacks are over a portion of the first semiconductor fin and a portion of the second semiconductor fin. The first and second S/Ds respectively covers another portion of the first semiconductor fin and another portion of the second semiconductor fin.

Abstract: This disclosure provides a lens assembly that has an optical path and includes a lens element and a light-blocking membrane layer. The lens element has an optical portion, and the optical path passes through the optical portion. The light-blocking membrane layer is coated on the lens element and adjacent to the optical portion. The light-blocking membrane layer has a distal side and a proximal side that is located closer to the optical portion than the distal side. The proximal side includes two extension structures and a recessed structure. Each of the extension structures extends along a direction away from the distal side, and the extension structures are not overlapped with each other in a direction in parallel with the optical path. The recessed structure is connected to the extension structures and recessed along a direction towards the distal side.

Abstract: A DDoS attack mitigation process, comprising: receiving a request from a client device; computing a data access frequency for the client device, data access frequency being a number of requests received from the client device within a set period of time; comparing the data access frequency to a threshold value, wherein a DDoS attack is suspected if the data access frequency is higher than the threshold value; if a DDoS attack is not suspected, then the request being forwarded to the intended resource; else if a DDoS attack is suspected, then responding to the client user's device with a DDoS attack mitigation challenge webpage embedded with a user-interactive widget to the client user's device requiring the client device's user to drag a prompt icon along a movement path without interrupt for authentication.

Abstract: A charge-domain filter (CDF) apparatus and an operation method thereof are provided. The CDF apparatus includes an input-signal combination network (ISCN), a switch-capacitor network (SCN) module, an output-signal combination network (OSCN), and a bandwidth compensation network (BCN). The input terminal of the ISCN receives an input signal. The SCN module is connected between the ISCN and the OSCN. The OSCN outputs an output signal of the CDF apparatus. The BCN senses the signal of the SCN module, senses the signal of the OSCN, or senses the signal of each of the SCN module and the OSCN, and correspondingly generates a forward signal or a feedback signal for the ISCN or the OSCN according to the sensing result to perform bandwidth compensation.

Abstract: A charge-domain filter (CDF) apparatus and an operation method thereof are provided. The CDF apparatus includes an input-signal combination network (ISCN), a switch-capacitor network (SCN) module, an output-signal combination network (OSCN), and a bandwidth compensation network (BCN). The input terminal of the ISCN receives an input signal. The SCN module is connected between the ISCN and the OSCN. The OSCN outputs an output signal of the CDF apparatus. The BCN senses the signal of the SCN module, senses the signal of the OSCN, or senses the signal of each of the SCN module and the OSCN, and correspondingly generates a forward signal or a feedback signal for the ISCN or the OSCN according to the sensing result to perform bandwidth compensation.

Abstract: A charge domain filter (CDF) is provided. The CDF includes a switched-capacitor network (SCN) and a clock generator. An input of the SCN receives an input signal. The SCN samples the input signal according to clock signals with different phases. The clock generator is coupled to the SCN for providing the clock signals. The clock generator adjusts phase differences of the clock signals or pulse widths of the clock signals in accordance with a control signal.

Abstract: A charge domain filter (CDF) and a method thereof are provided. The CDF includes an amplifier, a first switch-capacitor network (SCN), a second SCN, a third SCN and a fourth SCN. Input terminals of the first and the second SCNs are coupled to first and second output terminals of the amplifier, respectively. Input and output terminals of the third SCN are coupled to output terminals of the first and the second SCNs, respectively. Input and output terminals of the fourth SCN are coupled to output terminals of the second and the first SCNs, respectively. A mode control terminal of the third SCN receives a first mode signal to set an impulse response mode of the third SCN. A mode control terminal of the fourth SCN receives a second mode signal to set an impulse response mode of the fourth SCN.

Abstract: A charge domain filter (CDF) is provided. The CDF includes a switched-capacitor network (SCN) and a clock generator. An input of the SCN receives an input signal. The SCN samples the input signal according to clock signals with different phases. The clock generator is coupled to the SCN for providing the clock signals. The clock generator adjusts phase differences of the clock signals or pulse widths of the clock signals in accordance with a control signal.

Abstract: A down conversion filter with a plurality of sampling capacitor, wherein at least one sampling capacitor is discharged in sampling phases or charge-summing phases of the other sampling capacitors.

Abstract: A charge domain filter (CDF) is provided. The CDF includes a switched-capacitor network (SCN) and a clock generator. An input of the SCN receives an input signal. The SCN samples the input signal according to clock signals with different phases. The clock generator is coupled to the SCN for providing the clock signals. The clock generator adjusts phase differences of the clock signals or pulse widths of the clock signals in accordance with a control signal.

Abstract: A charge domain filter (CDF) apparatus having a bandwidth compensation circuit is provided. The bandwidth compensation circuit includes a configurable power-reference cell (CPC) and/or a programmable-delay cell (PDC). The CPC receives and adjusts an output of the CDF to obtain a sensing power, and outputs the sensing power to the CDF. The PDC receives and delay an output of the CDF, and outputs a delay result to the CDF. The bandwidth compensation circuit having a flexible structure, so as to implement X-axis (frequency) compensation and/or Y-axis (power or gain) compensation of a frequency response diagram according to a design requirement.

Abstract: A charge domain filter (CDF) and a method thereof are provided. The CDF includes an amplifier, a first switch-capacitor network (SCN), a second SCN, a third SCN and a fourth SCN. Input terminals of the first and the second SCNs are coupled to first and second output terminals of the amplifier, respectively. Input and output terminals of the third SCN are coupled to output terminals of the first and the second SCNs, respectively. Input and output terminals of the fourth SCN are coupled to output terminals of the second and the first SCNs, respectively. A mode control terminal of the third SCN receives a first mode signal to set an impulse response mode of the third SCN. A mode control terminal of the fourth SCN receives a second mode signal to set an impulse response mode of the fourth SCN.

Abstract: A charge domain filter (CDF) is provided. The CDF includes a switched-capacitor network (SCN) and a clock generator. An input of the SCN receives an input signal. The SCN samples the input signal according to clock signals with different phases. The clock generator is coupled to the SCN for providing the clock signals. The clock generator adjusts phase differences of the clock signals or pulse widths of the clock signals in accordance with a control signal.

Abstract: A down-conversion filter is provided, using first and second input terminals to receive signals that are differentially outputted by a preceding circuit, and using an output terminal to output a down-converted and filtered signal. An output capacitor is coupled to the output terminal. A first switched-capacitor network is arranged between the first input terminal and the output terminal. A second switched-capacitor network is arranged between the second input terminal and the output terminal. Each switched-capacitor network has capacitors, charging switches and charge-summing switches. The charging switches are designed to alternatively couple the capacitors to the first (or second) input terminal. The charge-summing switches are designed to couple the capacitors to the output terminal.

Abstract: A charge domain filter with controllable transfer function is disclosed. The charge domain filter has a plurality of switched-capacitor networks, a switching device and a current adder. The switched-capacitor networks are interleaving controlled, and each have an input terminal and an output terminal, and the input terminals of all of the switched-capacitor networks are connected together to be coupled to an input signal. The switching device is designed for transfer function control, and is operated according to a switch control signal. The switching device determines connections between the output terminals of the switched-capacitor networks and how the output terminals of the switched-capacitor networks are coupled to the current adder and thereby generates at least one current adder input. The at least one current adder input is received by the current adder, and the current adder outputs an output signal accordingly.

Abstract: A charge domain filter (CDF) and a bandwidth compensation circuit of the CDF are provided. The CDF includes an amplifier, a plurality of switch-capacitor networks (SCNs), a connector, a current adder (CA) and a bandwidth compensation circuit. A first input terminal of the amplifier receives an input signal, and an output terminal thereof is connected to input terminals of the SCNs. The connector is connected between the output terminal of the SCNs and the CA for configuring coupling status of the output terminals of the SCNs and input terminals of the CA. The bandwidth compensation circuit senses a portion of or all of the output terminals of the SCNs and the CA, and outputs the sensing result to a second input terminal of the amplifier.

Abstract: A backlight module includes a light guide plate having a light incident surface, a light source module, at least one catch member, and a cushion member. The light source module is disposed adjacent to the light incident surface and has at least one light-emitting element, wherein a light beam emitted by the light-emitting element is capable of entering the light guide plate through the light incident surface. The catch member engages with one end of the light source module, wherein the catch member has at least one extension part extending towards the light incident surface of the light guide plate, and the extension part has an end surface facing the light incident surface. The cushion member is disposed between the light guide plate and the light source module and is adjacent to the light incident surface of the light guide plate and the end surface of the catch member.

Abstract: A charge domain filter (CDF) and a bandwidth compensation circuit of the CDF are provided. The CDF includes an amplifier, a plurality of switch-capacitor networks (SCNs), a connector, a current adder (CA) and a bandwidth compensation circuit. A first input terminal of the amplifier receives an input signal, and an output terminal thereof is connected to input terminals of the SCNs. The connector is connected between the output terminal of the SCNs and the CA for configuring coupling status of the output terminals of the SCNs and input terminals of the CA. The bandwidth compensation circuit senses a portion of or all of the output terminals of the SCNs and the CA, and outputs the sensing result to a second input terminal of the amplifier.

Abstract: A charge domain filter with controllable transfer function is disclosed. The charge domain filter has a plurality of switched-capacitor networks, a switching device and a current adder. The switched-capacitor networks are interleaving controlled, and each have an input terminal and an output terminal, and the input terminals of all of the switched-capacitor networks are connected together to be coupled to an input signal. The switching device is designed for transfer function control, and is operated according to a switch control signal. The switching device determines connections between the output terminals of the switched-capacitor networks and how the output terminals of the switched-capacitor networks are coupled to the current adder and thereby generates at least one current adder input. The at least one current adder input is received by the current adder, and the current adder outputs an output signal accordingly.