Patent application number | Description | Published |
20100042879 | Method of memory build-in self-test - The present invention discloses a memory build-in self-test comprising steps of: (a) determining whether there is redundant address in the ROM; (b) when there is redundant address for storing standard check code, transferring the coefficient file in the ROM to a predetermined format; (c) producing a self-test logic and a standard check code corresponding to the ROM via design tool; (d) writing the standard check code into the redundant address and generating a new ROM. The present invention can assure that the standard check code and coefficient can be simply revised via corresponding way of Mask Change, so as to detect the damages of ROM by using memory build-in self-test (MBIST) which does not need to remake a whole set of Mask to revise the standard check code outside the ROM, so as to save cost and time, and lower the difficulty to update the product. | 02-18-2010 |
20110279162 | Signal conditioning system with a sigma-delta modulator - A signal conditioning system includes a first filter, a signal processing module connected with the first filter, a second filter connected with the signal processing module, and a Σ-Δ modulator connected with the second filter. The signal processing module makes the saturation overflow treatment to the signal output by the first filter using the characteristics of the radix complement adder. The Σ-Δ modulator is a high order filter formed by a plurality of cascaded and inter-stage feedback second-order filters. Based on the performance of the Σ-Δ modulator and the whole system, the stability of the signal conditioning system is improved. | 11-17-2011 |
20110299651 | Shift frequency demultiplier with automatic reset function - A shift frequency demultiplier with automatic reset function is N-frequency demultiplication (N>2) and includes N-1 registers connected with each other and defined from a first register to an (N-1)th register. Each of the registers has an input end, an output end, a reset end and a clock end. For the registers from the first register to the (N-2)th register, the output end of every register is connected with the input end of a next register adjacent thereto, the output end of the (N-1)th register is connected with the input end of the first register by a reverser. The reset end of the (N-1)th register is connected with a system reset signal end. The system reset signal end logically multiplied by the output end of the (N-1)th register is connected with the reset ends of the registers from the first register to the (N-2)th register. | 12-08-2011 |
20140089372 | Divider Logic Circuit and Implement Method Therefor - A divider logic circuit for obtaining a quotient S of a dividend M divided by a divisor N, includes a first constant value input terminal, a first adder, a second constant value input terminal, a base number input terminal, at least one integer power device, at least one right shift register, a second adder, and a multiplier; wherein the integer power device determines a first constant value that the base number is N | 03-27-2014 |
20140143583 | Circuit for generating USB peripheral clock and method therefor - A circuit for generating USB peripheral clock comprises: an internal oscillator, a controllable frequency divider, a frequency multiplier, a receiving counter and a frequency division controller, wherein the internal oscillator generates a clock having a fixed frequency; the controllable frequency divider processes frequency division on the clock generated by the internal oscillator; the frequency multiplier processes frequency multiplication on the clock after frequency division and transmits the clock after frequency multiplication to the USB main structure; the receiving counter receives an SOF packet which is transmitted by a host according to the clock outputted by the frequency multiplier, and counts intervals of receiving the SOF packet; and the frequency division controller compares the difference between the counting result of the receiving counter and a standard interval, controls and regulates frequency division parameters of the controllable frequency divider according to a comparing result thereof. | 05-22-2014 |
20140143584 | Circuit for generating peripheral clock for USB and method therefor - A circuit for generating a peripheral clock for USB, provided on a USB major structure, comprises an internal oscillator, a receiver, a transmitter, a clock counter, and a clock processor; wherein the internal oscillator generates a clock having a settled frequency; the receiver is connected with the internal oscillator and a system unit, and receives a packet transmitted by the system unit; the transmitter is connected with the internal oscillator and the system unit, and transmits a packet of the USB major structure to the system unit; the clock counter is connected with the receiver and the internal oscillator, and counts a length of the packet received; and the clock processor is connected with the clock counter, the internal oscillator, and the transmitter, and controls and adjusts a length of the packet transmitted by the transmitter according to the length of the packet counted by the clock counter. | 05-22-2014 |
20150082073 | Circuit and method for producing USB host working clock - A circuit for producing USB host working clock comprises: an internal oscillator, a controllable frequency divider, a frequency multiplier, a USB host interface, and a frequency division controller. According to the frequency multiplier providing clock, the USB host interface configures with USB peripherals for responding. The frequency division controller is connected to the USB host interface and the controllable frequency divider. The USB host interface transmits a response result that the USB host interface configures with USB peripherals for responding to the frequency division controller. According to the USB host interface feeding back the response result, the frequency division controller regulates a frequency dividing ratio of the controllable frequency divider in set scope of the frequency dividing ratio. After regulating the frequency dividing ratio of the controllable frequency divider, the frequency division controller controls the controllable frequency divider that is processed with frequency division in fixed frequency dividing ratio. | 03-19-2015 |
20150117590 | Shift frequency demultiplier - A shift frequency demultiplier includes: an inverter; N-2 registers; and N-4 OR gates; wherein an output terminal of the No. N-2 register is connected to an input terminal of the inverter, an output terminal of the inverter is connected to an input terminal of the No. 1 register and input terminals of the OR gates; the output terminal of the No. 1 register is connected to another input terminal of the No. 1 OR gate, the output terminal of the No. N-4 register is connected to another input terminal of the No. N-4 OR gate; an output terminal of the No. 1 OR gate is connected to the input terminal of the No. 2 register, an output terminal of the No. N-4 OR gate is connected to the input terminal of the No. N-3 register whose the output terminal is connected to an input terminal of the No. N-2 register. | 04-30-2015 |