Abstract: Provided is a touch-panel device capable of detecting a touched position with high accuracy even when a touched area extends off an electrode area. According to the present invention, the touched area is assumed to be, for example, a circular in shape. A width in an X direction (overlap width (X46)) and a width in a Y direction (overlap width (Y47)) of an area where the touched area in a circular shape and an electrode area (6) overlap each other may be determined based on sensor measured values. When the overlap width (X46) and the overlap width (Y47) are different from each other, it is judged that the touched area extends off the electrode area, and a position of a center of the touched area in the circular shape is calculated as the touched position.

Abstract: A PWM signal generation circuit in an IPM includes an amplification circuit amplifying a voltage across terminals of a temperature sensor, a comparison circuit generating a PWM signal based on a triangular wave signal and an output signal of the amplification circuit, and a correction circuit setting an amplification ratio of the amplification circuit such that a pulse width of the PWM signal is set to a reference pulse width in an adjustment mode in which a switching element is caused to have a reference temperature. Consequently, characteristic variations in the temperature sensor, the amplification circuit, and the like can be corrected, and the temperature of the switching element can be detected with high accuracy.

Abstract: The display device is provided with X electrodes XP and Y electrodes YP which cross with a first insulating layer in between and a number of Z electrodes which are electrically floating from each other with a second insulating layer in between. The Z electrodes are arranged so that each Z electrode overlaps both an adjacent X electrode and Y electrode. The pad portion of a first X electrode has such a form that the area is maximum in the vicinity of the fine wire portion of the first X electrode and the area is minimum in the vicinity of the fine wire portion of an adjacent second X electrode, and the area of the pad portion is smaller towards the direction in which the distance increases away from the vicinity of the fine wire portion of the first X electrode. A pulse signal is sequentially applied to one set of X electrodes or Y electrodes.

Abstract: A capacitance detection device of a capacitance system includes: a capacitance sensor electrode for detecting a capacitance; a power source for supplying charges to be charged in the capacitance sensor electrode; an electric charge storage capacitor in which an amount of charges to be charged therein changes according to the electric charges charged in the capacitance sensor electrode; and a switch for changing a reference potential of the electric charge storage capacitor. The reference potential of the electric charge storage capacitor is changed in a period of measuring the capacitance.

Abstract: In a touched position detection method for a touch panel for detecting a touched position, based on measured values by a plurality of sensors, presence of a touch is determined when a measured value by a sensor exceeds a touch threshold. As a touch threshold, a value which cannot be attained due to a mere noise but can due to presence of a touch is set. With respect to sensors located in the vicinity of a sensor showing a high measured value, a higher weighted value is applied to modify a measured value in a touched position calculation process than that to be applied to other sensors.

Abstract: A detection resolution is improved in a display device that employs an electrostatic capacity coupling type touch panel provided with a transparent conductive film serving as a detection film. A plurality of electrode terminals (102) is provided such that at least three electrode terminals (102) are aligned in each side of a detection transparent conductive film (101). A touch panel control circuit is provided for selecting one of two to four numbers of electrode terminals from among the plurality of electrode terminals (102) of the detection transparent conductive film (101), applying an AC signal provided from a signal source (105) through a current detection resistor (r) (103), and then detecting a current that flows through each of the selected electrode terminals.

Abstract: Provided is a capacitance coupling type on-screen input image display device that enables multipoint detection in a short period of time. The on-screen input image display device includes: a detection circuit (4) for detecting a change in capacitance between the plurality of X coordinate electrodes and the plurality of Y coordinate electrodes of the touch sensor (3); a touch panel control circuit (6) for determining a touched coordinate point; and a main control circuit (7) for receiving touch coordinate data from the touch panel control circuit (6). The main control circuit (7) judges occurrence of a user's touch and coordinates of the occurrence from the touch coordinate data, and supplies a display signal corresponding to the judged coordinates to the display device (1) via the display control circuit (2), whereby the display signal is reflected on the display.

Abstract: In a touch panel capable of detecting the coordinates of two pressed-down points individually at the same time, the coordinates detected while one point is pressed are stored and, if a second point is subsequently pressed, the stored coordinates of a first point are used to identify the coordinates closer to the stored coordinates as the first point and the coordinates of another detected point as the second point, thereby identifying an order in which the two points are pressed. Thereafter, what mouse operation has been executed at the coordinates of the first point is detected based on a positional relation between the coordinates of the first point and the coordinates of the second point, and a result of the detection is output to an application operable through a graphical user interface.

Abstract: A TFT element for ambient light detection and a TFT element for temperature detection are connected in series. In a first period, a first switch element is off, and a second switch element is at a hi side, so that a threshold voltage of the TFT element for temperature detection is detected. In a second period, a first switch element is on, and a second switch element is at a low side, so that temperature is detected. In a third period, a first switch element is on, and a second switch element is at a hi side, so that ambient light is detected. An input voltage and a control voltage to each of the TFT elements are set by a voltage controller provided in a drive circuit based on the threshold voltage.

Abstract: A data driver circuit is divided into a low potential region, an intermediate potential region, and a high potential region, and relative withstand voltages in the respective regions are set equal to each other. Both of the transmission of a power source voltage to the high potential region from the low potential region and the transmission of video signals are performed via the intermediate potential region. Due to such a constitution, the withstand voltages in the respective regions can be suppressed to low values.

Abstract: A PWM signal generation circuit in an IPM includes an amplification circuit amplifying a voltage across terminals of a temperature sensor, a comparison circuit generating a PWM signal based on a triangular wave signal and an output signal of the amplification circuit, and a correction circuit setting an amplification ratio of the amplification circuit such that a pulse width of the PWM signal is set to a reference pulse width in an adjustment mode in which a switching element is caused to have a reference temperature. Consequently, characteristic variations in the temperature sensor, the amplification circuit, and the like can be corrected, and the temperature of the switching element can be detected with high accuracy.

Abstract: Tonal data of one frame of a video signal is subject to time division into dark subframe tonal data at a low tone and bright subframe tonal data at a high tone to compensate for a lowered luminance in the dark subframe by the bright subframe so as not to change an integrated luminance per one ordinary frame. Subframe tonal data read from a memory is converted into output tonal data constituted of dark subframe tonal data at a low tone and bright subframe tonal data at a high tone, by four arithmetic calculation operations using calculation parameters supplied from a register.

Abstract: An interface circuit includes a detector to detect a particular pattern from a sequence of output data, a shift clock generator to change a cycle of a shift clock according to the detection result, a shift register section to change a data output width by the shift clock and output it as drive data, and an open-drain output section including an N-channel transistor driven by the drive data and a pull-up resistor. The detector detects a sequence where the current output data is “0” and the next output data is “1”, and the shift clock generator shortens and extends the cycles of the shift clock corresponding to “0” and “1”, respectively.

Abstract: In a display driving circuit according to the present invention, not all the pixel values (example : 0˜255) but only the values (example : 179˜255) of the significant partial range (N˜100%) have data of histogram of pixels of an image as a partial histogram, and when the pixel (Ds) at the significant t% rank order of the entire histogram is within the range of the partial histogram, the display driving circuit performs its operation in the same manner as in the case where it has the entire histogram, and when the pixel (Ds) is out of the range, the display driving circuit uses the range minimum value (N) in the place of the pixel of the significant t% rank order and performs its operation.

Abstract: In a driving device (20) for driving an IGBT (1), a current measuring portion (22) measures a main current amount flowing through the IGBT (1). When the main current amount measured by the current measuring portion (22) reaches a predetermined reference level, a protection circuit portion (23) limits the main current at the IGBT (1) to protect it. A temperature measuring portion (24) measures the temperature of the IGBT (1). The control portion (25) adjusts the aforementioned reference level based on the temperature of the IGBT (1) measured by the temperature measuring portion (24). A control portion (35) stores setting values of the reference level as data.

Abstract: A synchronization compensating circuit for use in a scanning type display circuit, comprises a first multistage delay circuit receiving a basic clock for generating K delayed clocks, a second multistage delay circuit receiving an output of the first multistage delay circuit for generating L delayed clocks, and a timing signal generating circuit receiving a horizontal synchronization signal for generating a latch signal. A first selection signal generation circuit latches a first phase of the basic clock and the K delayed clocks in response to the latch signal, and a second selection signal generation circuit latches a second phase of the basic clock and the K delayed clocks in response to the latch signal. A third selection signal generation circuit latches the L delayed clocks in response to the latch signal. Each of the first to third selection signal generation circuit generates a selection signal corresponding to a received clock fulfilling a predetermined condition.

Abstract: For allowing a port to serve as not only one of the system clock input port but also a data input/output port, there is disclosed a data processing unit comprising a system clock supplying circuit operative in an internal oscillation mode or a transmission mode depending upon a mode selecting signal, a shifting circuit operative to provide an electrical path between two ports and the system clock supplying circuit in the internal oscillation mode but to provide another electrical path between one of the two ports and a data input/output line in the transmission mode, so that one of the ports serves between the clock input port and the data input/output port depending upon the mode selecting signal.