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| 12-Bit 50 MSPS ADC in IBM 180 SOI | 参考报价 | 280.000 μm^2 | 50 MHz | 180 nm |  |
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| MICIP_ADC12 is compact and low power 12-bit analog-to-digital converter silicon IP. This ADC uses 1.5b/stage pipelined architecture optimized for low power and small area. | 概述 | |||||
| Triple 10-bit 330 MSPS Video DAC IP in TSMC 90 nm | 参考报价 | 330.000 μm^2 | 330 MHz | 90 nm | |
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| is a 10-bit Triple DAC designed in TSMC 90 nm logic process. It consists of a current steering DAC. The DAC uses a fully differential architecture. The input data of the DAC is in 1.2 V, in unsigned format. | 概述 | |||||
| Dual-Channel 12-bit 80 MSPS ADC IP in UMC 65 nm | 参考报价 | 450.000 μm^2 | 0.8 MHz | 65 nm | |
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| ADC X is an ultra-compact and very low power analog-to-digital converter (ADC) IP. The 12-bit 80 MSPS Dual ADC includes an internal custom bandgap voltage reference. It is capable of supplying bias currents to other parallel ADCs. IP architecture is robust and can be ported to other 65 nm processes.The ADC uses fully differential pipeline architecture with custom low-disturbance digital correction technique which allows single supply bus for both digital and analog. | 概述 | |||||
| Asynchronous I2C Slave | 999 点 | 578.000 Gates | 100 MHz | 130 nm | |
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| Unlike Synchronous type I2C slave design need clock to work. This Asynchronous type don’t need base clock . It is very power saving in some application Application : - Power manager IC - Sensor IC - Software wakeup requirement system | 概述 | |||||
| 12-Bit 800KSPS Low Power SAR-ADC | 参考报价 | 无资料 | 25 MHz | 180 nm | |
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| The SAR-ADC is a low power ADC that is implemented in Successive Approximation architecture. It can provide 12-bit resolution capability with only 3V supply voltage. It accepts an analog input range from 0 to VCC and digitizes the input at a maximum sampling frequency rate of 800KHz at 5V supply voltage. This ADC also includes MUX design to select 0 of 7 analog inputs. The power dissipation is less than 5mW with 5V power supply. This SAR-ADC is implemented in SMIC 0.18μm generic CMOS technology. | 概述 | |||||
| AES Codec with 8-bit datapath | 20000 点 | 1.300 K Gates | 515 MHz | 180 nm | |
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| The IP core implements the NIST FIPS-197 Advanced Encryption Standard and can be programmed to either encrypt or decrypt 128-bit blocks of data using a 128-bit, 192-bit or 256-bit key. The IP has been carefully designed to require minimum logic resources rendering it an ideal solution for low power applications. This has been achieved by using an 8-bit data path size which means that 16 clock cycles are required to load/unload the 128-bit plaintext/ciphertext block. The encryptor receives the 128-bit plaintext block in 8-bit input symbols and generates the corresponding 128-bit ciphertext block in 8-bit output symbols using a supplied 128, 192, or 256-bit AES key. The pre-computed key values are read from an internal round key RAM. A key expander module is provided as an optional module to allow automatic generation and loading of the round key RAM. The decryptor implements the reverse function, generating plaintext from supplied ciphertext, using the same AES key as was used for encryption. The implementation is very low on latency, high speed with a simple interface for easy integration in SoC applications. | 概述 | |||||
| One Wire Communication | 1200 点 | 1.500 K Gates | 100 MHz | 130 nm | |
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| In some particular application, few pin count but still need chip to chip communication. This IP use one wire bi-direction (open drain) to communication. Just like UART , it is consist of one TX and one RX. User can define their own payload freedomly. All devices are connecting through open-drain pull high bus. Every device can send data to others actively. Waveform Application - Analog IC debug - MCU program port - Low pin count IC | 概述 | |||||
| Configurable Reed Solomon Encoder | 30000 点 | 2.500 K Gates | 250 MHz | 180 nm | |
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| Our IP core implements the Reed Solomon encoding algorithm and is parameterized in terms of bits per symbol, maximum codeword length and maximum number of parity symbols. It also supports varying on the fly shortened codes. Therefore any desirable code-rate can be easily achieved rendering the decoder ideal for fully adaptive FEC applications. ntRSE core supports continuous or burst decoding. The implementation is very low latency, high speed with a simple interface for easy integration in SoC applications. | 概述 | |||||
| Octal SPI Master/Slave Controller | 参考报价 | 4.641 K Gates | 500 MHz | 无资料 | |
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| Designed to work with a wide variety of SPI bus variants, the core supports run-time control of several SPI protocol parameters. For example, the SPI frame width can be 1 to 4 bytes, the most significant bit position in a frame, serial clock phase and polarity are all software- programmable. In master mode the core can control up to 32 slaves. A software controllable clock generator derives the serial clock for master mode, by dividing the frequency of a clock line dedicated for that purpose | 概述 | |||||
| BRAINS | 50000 点 | 5.250 K Gates | 1.2 GHz | 40 nm | |
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| With improvement of technology node and IC design is geting more complex, the ratio of embedded memory in SoCs have been exceeding 50%. The fault types of memory are getting complex. The Memory BIST (Built-In Self-Test) is generated for efficient controlling IC cost. The traditional BIST method is inserted along with single memory. If there are many memories in SoCs, the area and testing time of SoCs are expanded a lot due to insertion of BIST. Therefore the SoCs' cost will increase rapidly because memory testing time is too long. We devoted in developing SRAM testing solutions for a long time. BRAINS is based on memory testing patents to reduce testing time and increase yield rate. In addition, BRAINS has many unique features to increase SoCs' reliability and stability. | 概述 | |||||
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