An apparatus comprising: circuitry configured to classify a signal; and circuitry configured to control saving of the signal to a memory with a conditional resolution, wherein a signal that is classified as anomalous is saved at higher resolution as a higher resolution signal and a signal that is not classified as anomalous is saved at lower resolution as a lower resolution signal or is not saved.

Digital-to-analog converter (DAC) circuitry for providing currents at electrodes of an Implantable Pulse Generator (IPG) is disclosed. The DAC circuitry includes at least one PDAC for sourcing current to the electrodes, and at least one NDAC for sinking current from the electrodes. The PDACs are powered with power supplies VH (the compliance voltage) and Vssh in a high power domain, and the NDACs are powered with power supplies Vcc and ground in a low power domain. VH may change during IPG operation, and Vssh preferably also changes with a fixed difference with respect to VH. Digital control signals to the PDACs are formed (and possibly converted into) the high power domain, and transistors used to build the PDACs are biased in the high power domain, and thus may also change with VH. This permits transistors in the PDACs and NDACs to be made from normal low-voltage logic transistors.

A time-sharing wave recording method is provided. Firstly, N1 operating variables are selected, and the storage addresses of the N1 operating variables are mapped to N1 index variables. Then, N2 record channels in a sequential relationship are provided, and a mapping relationship between each record channel and the N1 index variables is established. Then, the values of the operating variables are assigned to a first record channel of the N2 record channels in response to a rising edge of a pulse of a clock signal and a start triggering signal, the values of the operating variables are sequentially assigned to the rest of the N2 record channels in response to a rising edge of each pulse of the clock signal and the start triggering signal, and the assigned values of the operating variables for the N2 record channels are recorded to the memory.

A touch apparatus and a touch detection integrated circuit (IC) thereof are provided. The touch detection IC includes a driving signal generation circuit and a receiving circuit. The driving signal generation circuit is configured to control a touch panel to perform touch sensing operation and control a fingerprint sensor to perform fingerprint sensing operation. The receiving circuit receives and processes a touch signal of the touch panel during a first period when the driving signal generation circuit transmits the first driving signal for controlling the touch panel to perform touch sensing operation. The receiving circuit receives and processes a fingerprint signal of the fingerprint sensor during a second period when the driving signal generation circuit transmits the second driving signal for controlling the fingerprint sensor to perform fingerprint sensing operation.

A touch apparatus and a touch detection integrated circuit (IC) thereof are provided. The touch detection IC includes a driving signal generation circuit and a receiving circuit. The driving signal generation circuit is configured to control a touch panel to perform touch sensing operation and control a fingerprint sensor to perform fingerprint sensing operation. The receiving circuit receives and processes a touch signal of the touch panel during a first period when the driving signal generation circuit transmits the first driving signal for controlling the touch panel to perform touch sensing operation. The receiving circuit receives and processes a fingerprint signal of the fingerprint sensor during a second period when the driving signal generation circuit transmits the second driving signal for controlling the fingerprint sensor to perform fingerprint sensing operation.

A control system that distributes information from a control device to a reception device includes a read request transmission unit that transmits a read request for information to the control device, an information generation unit that generates information in response to the read request, an information transmission unit that transmits the generated information to the reception device, and a distribution cycle computation unit that computes a distribution cycle based on a generation interval of the read request. The information transmission unit transmits the information in accordance with the distribution cycle computed by the distribution cycle computation unit.

A control system that distributes information from a control device to a reception device includes a read request transmission unit that transmits a read request for information to the control device, an information generation unit that generates information in response to the read request, an information transmission unit that transmits the generated information to the reception device, and a distribution cycle computation unit that computes a distribution cycle based on a generation interval of the read request. The information transmission unit transmits the information in accordance with the distribution cycle computed by the distribution cycle computation unit.

A system for quantitative water management comprises: at least two interconnected water production entities (U), at least one water resource (S) linked to one at least of the production entities (U), at least one demander element (D) requesting water produced defined by a pre-established temporal curve of water demand produced as a function of time, each link between production entities (U), water resources (S) and demander elements (D) being ensured by a transfer work (C) having a predetermined maximum flowrate and being able to be interconnected, each production entity (U) and each water resource (S) furthermore being associated with a weighting function P, and a calculator adapted to minimize the global weighting function Pg of the system while guaranteeing compliance with the pre-established temporal curve of water demand produced of each demander element (D) under constraint of compliance with the maximum flowrates of the various elements of the system.

A sensor-equipped display device includes a scanning driving unit (4) that repeats a scanning operation of selecting scanning lines (G) sequentially in a first direction, and a data driving unit (5) that applies a voltage to data lines (S). The display device further includes a detection control unit (30) that repeats a scanning operation of driving drive lines (DRL) sequentially in the first direction, and detects signals of detection lines (SNL). During a period that overlaps a period for the screen scanning operation with respect to the scanning lines, the detection control unit executes the screen scanning operation with respect to the drive lines, and in the screen scanning operation with respect to the drive lines, the detection control unit outputs the driving signal, avoiding the drive line in an area corresponding to the scanning line that is being selected by the scanning driving unit.

A sensor-equipped display device includes a scanning driving unit (4) that repeats a scanning operation of selecting scanning lines (G) sequentially in a first direction, and a data driving unit (5) that applies a voltage to data lines (S). The display device further includes a detection control unit (30) that repeats a scanning operation of driving drive lines (DRL) sequentially in the first direction, and detects signals of detection lines (SNL). During a period that overlaps a period for the screen scanning operation with respect to the scanning lines, the detection control unit executes the screen scanning operation with respect to the drive lines, and in the screen scanning operation with respect to the drive lines, the detection control unit outputs the driving signal, avoiding the drive line in an area corresponding to the scanning line that is being selected by the scanning driving unit.