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| WiFi Frequency Synthesizer IP In 2.4GHz Band | 100000 Points | 200.000 K μm^2 | 3.2 GHz | 55 nm |  |
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| The frequency synthesizer uses a single 1.25V power supply. Good noise immunity allows this IP to be integrated in a noisy SOC environment. The synthesizer operates at 1.5X WiFi 2.4GHz band for wireless application. | Introduction | |||||
| 10-bit 300 MSPS Video DAC IP in 90 nm | 60000 Points | 76.000 K μm^2 | 300 MHz | 90 nm | |
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| The UIP_DAC10-300M_205370 is a 10-bit DAC designed in low power 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 1.2V, in unsigned format. A 3.3V supply is used for the analog portion of the IP. This high performance DAC is designed for CVBS standard or RGB Video signal bandwidth. The IP consumes only 41 mA at 300 MSPS operation and utilizes a silicon area of only 0.076 mm2. The IP does not require any external decoupling and is ideal for integration in mixed-signal systems. The DAC output current is 6-bit programmable. The IP architecture is robust and can be ported to other 90 nm processes. APPLICATIONS Composite Video (CVBS) HDTV RGB Video DAC Output Model | Introduction | |||||
| 10-bit 165 MSPS ADC IP in 28 nm | 80000 Points | 70.000 K μm^2 | 165 MHz | 28 nm | |
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| UIP_ADC10_165M_809744 is an ultra-compact and very low power analog-to-digital converter (ADC) silicon IP. The 10-bit 165 MSPS ADC includes an internal custom bandgap voltage reference. It is capable of supplying bias currents to other parallel ADCs. The ADC uses fully differential pipeline architecture with custom low-disturbance digital correction technique which allows single supply bus for both digital and analog. The ADC is designed for high dynamic performance for input frequencies up to Nyquist. This makes the IP perfectly suitable for video, imaging and communication appliances. The IP is available in different metal options as well as deep N-well (DNW) option for SoC with high level of substrate noise. It consumes only 12mW at 165 MSPS operation and requires silicon area of 0.07 mm2. The IP does not require any external decoupling and is ideal for integration in mixed-signal systems. The output data of ADC is available in 2’s complement format. UIP_ADC10_165M_809744 can be used in the following applications: ‧Digital imaging ‧TV/Video ‧Wireless LAN ‧Rx communication channel ‧IOT | Introduction | |||||
| One Wire Communication | 1200 Points | 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 | Introduction | |||||
| Asynchronous I2C Slave | 999 Points | 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 | Introduction | |||||
| 10-bit 165 MSPS ADC IP in 28 nm | 80000 Points | 70.000 K μm^2 | 165 MHz | 28 nm | |
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| UIP_ADC10_165M_564144 is an ultra-compact and very low power analog-to-digital converter (ADC) silicon IP. The 10-bit 165 MSPS ADC includes an internal custom bandgap voltage reference. It is capable of supplying bias currents to other parallel ADCs. The ADC uses fully differential pipeline architecture with custom low-disturbance digital correction technique which allows single supply bus for both digital and analog. The ADC is designed for high dynamic performance for input frequencies up to Nyquist. This makes the IP perfectly suitable for video, imaging and communication appliances. The IP is available in different metal options as well as deep N-well (DNW) option for SoC with high level of substrate noise. It consumes only 12mW at 165 MSPS operation and requires silicon area of 0.07 mm^2. The IP does not require any external decoupling and is ideal for integration in mixed-signal systems. The output data of ADC is available in 2’s complement format. UIP_ADC10_165M_564144 can be used in the following applications: ‧Digital imaging ‧TV/Video ‧Wireless LAN ‧Rx communication channel | Introduction | |||||
| SPI slave in mode 2 | 1000 Points | 254.000 Gates | 192 MHz | 130 nm | |
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| The Serial Peripheral Interface (SPI) bus, established by Motorola, is a synchronous serial data link. It operates in master/slave and full duplex styles. That is, when a master device initiates a transaction and communicates with a certain slave device, they exchange data bit-by-bit. Furthermore, the single master communication is applied to the SPI bus. Thus, there is always a single master device (with one or more slave devices) on it. The SPI bus contains 4 wires, with each named SCK, MOSI, MISO and SS_n respectively. You may also find alternative naming conventions elsewhere. The following table lists their functions and directions: The typical SPI bus architecture is designed as follows: When the SPI master device wants to communicate with a certain slave device, it asserts the SS_n line of that slave device, and then exchange data using the MOSI and MISO lines based on the toggling SCK line. With clock polarity (CPOL) and clock phase (CPHA) set to different values, the SPI bus can operate in 4 modes. These modes are listed in the following table, where provide means that the communicating master and slave devices provide data on the MOSI and MISO lines respectively on the other hand, capture means that the communicating master and slave devices capture data on the MISO and MOSI lines respectively: | Introduction | |||||
| SPI slave in mode 1 | 1000 Points | 276.000 Gates | 285 MHz | 130 nm | |
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| The Serial Peripheral Interface (SPI) bus, established by Motorola, is a synchronous serial data link. It operates in master/slave and full duplex styles. That is, when a master device initiates a transaction and communicates with a certain slave device, they exchange data bit-by-bit. Furthermore, the single master communication is applied to the SPI bus. Thus, there is always a single master device (with one or more slave devices) on it. The SPI bus contains 4 wires, with each named SCK, MOSI, MISO and SS_n respectively. You may also find alternative naming conventions elsewhere. The following table lists their functions and directions: The typical SPI bus architecture is designed as follows: When the SPI master device wants to communicate with a certain slave device, it asserts the SS_n line of that slave device, and then exchange data using the MOSI and MISO lines based on the toggling SCK line. With clock polarity (CPOL) and clock phase (CPHA) set to different values, the SPI bus can operate in 4 modes. These modes are listed in the following table, where provide means that the communicating master and slave devices provide data on the MOSI and MISO lines respectively on the other hand, capture means that the communicating master and slave devices capture data on the MISO and MOSI lines respectively: | Introduction | |||||
| SPI slave in mode 0 | 1000 Points | 274.000 Gates | 243 MHz | 130 nm | |
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| The Serial Peripheral Interface (SPI) bus, established by Motorola, is a synchronous serial data link. It operates in master/slave and full duplex styles. That is, when a master device initiates a transaction and communicates with a certain slave device, they exchange data bit-by-bit. Furthermore, the single master communication is applied to the SPI bus. Thus, there is always a single master device (with one or more slave devices) on it. The SPI bus contains 4 wires, with each named SCK, MOSI, MISO and SS_n respectively. You may also find alternative naming conventions elsewhere. The following table lists their functions and directions: The typical SPI bus architecture is designed as follows: When the SPI master device wants to communicate with a certain slave device, it asserts the SS_n line of that slave device, and then exchange data using the MOSI and MISO lines based on the toggling SCK line. With clock polarity (CPOL) and clock phase (CPHA) set to different values, the SPI bus can operate in 4 modes. These modes are listed in the following table, where provide means that the communicating master and slave devices provide data on the MOSI and MISO lines respectively on the other hand, capture means that the communicating master and slave devices capture data on the MISO and MOSI lines respectively: | Introduction | |||||
| SPI slave in mode 3 | 1000 Points | 256.000 Gates | 285 MHz | 130 nm | |
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| The Serial Peripheral Interface (SPI) bus, established by Motorola, is a synchronous serial data link. It operates in master/slave and full duplex styles. That is, when a master device initiates a transaction and communicates with a certain slave device, they exchange data bit-by-bit. Furthermore, the single master communication is applied to the SPI bus. Thus, there is always a single master device (with one or more slave devices) on it.The SPI bus contains 4 wires, with each named SCK, MOSI, MISO and SS_n respectively. You may also find alternative naming conventions elsewhere. The following table lists their functions and directions:The typical SPI bus architecture is designed as follows:When the SPI master device wants to communicate with a certain slave device, it asserts the SS_n line of that slave device, and then exchange data using the MOSI and MISO lines based on the toggling SCK line.With clock polarity (CPOL) and clock phase (CPHA) set to different values, the SPI bus can operate in 4 modes. These modes are listed in the following table, where provide means that the communicating master and slave devices provide data on the MOSI and MISO lines respectively on the other hand, capture means that the communicating master and slave devices capture data on the MISO and MOSI lines respectively: | Introduction | |||||
| μIP | Price | Logic Gate Count | Clock Rate | Technology | Ratings | |
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