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| 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 | |||||
| 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 | |||||
| 4.2V-to-1.2V DC/DC Converter | By Quotes | 40.000 K μm^2 | 1 MHz | 130 nm | |
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| The DCDC12 is a 0.13μm DC to DC converter in buck mode cell that converters input voltage to a smaller output voltage. The output voltage can be programmed from 1.05V to 1.3V.An external 10uH inductor is necessary. | Introduction | |||||
| 4.2V-to-1.8V DC/DC Converter | By Quotes | 40.000 K μm^2 | 1 Hz | 130 nm | |
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| The DCDC18 is a 0.13μm DC to DC converter in buck mode cell that converters input voltage to a smaller output voltage. The output voltage can be programmed from 1.65V to 1.9V.An external 10uH inductor is necessary. | Introduction | |||||
| PLL with Multiple Output Frequency | By Quotes | 40.000 K μm^2 | 12.156 MHz | 130 nm | |
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| The PLL is a 0.13μm Phase-Locked Loop (PLL) cell that provides a clock multiplier that can generate a stable 48M/96M/120MHz/156MHz clock from a 12MHz clock source. This is a “generic” PLL which integrates the Voltage-Controlled Oscillator (VCO), Phase-Frequency Detector, Low Pass Filter, Loop Divider and Post Divider. This PLL provides an operating voltage range of 1.08V ~ 1.32V, and an operating junction temperature range of -40˚ ~ 125℃. | Introduction | |||||
| 32 bits RISC Microcontroller | By Quotes | 33.000 K Gates | 100 MHz | 180 nm | |
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| The CPU Core is a 32-bit microprocessor. It has a 32-bit data path, a 32-bit register bank, and 32-bit memory interfaces. The processor has a Harvard architecture, which means that it has a separate instruction bus and data bus. This allows instructions and data accesses to take place at the same time, and as a result of this, the performance of the processor increases because data accesses do not affect the instruction pipeline.However, the instruction and data buses share the same memory space (a unified memory system). In other words, you cannot get 8 GB of memory space just because you have separate bus interfaces. Applications Wearables IoT Motor Control Appliances Connectivity Smart home/building/enterprice/planet | Introduction | |||||
| 14-Bit 3 MSPS ADC in GSMC110nm | 60000 Points | 32.000 K μm^2 | 3 MHz | 110 nm | |
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| UIP_ADC14_3M_245303 is compact and low power 14-bit analog-to-digital converter silicon IP. It has 20 single-end input channel selection multiplexer or 10 differential input channels selection. This ADC uses fully differential SAR architecture optimized for low power and small area. The ADC is designed for high dynamic performance for input frequencies up to Nyquist rate. This ADC consumes 150 uA at 3 MSPS operation and occupies silicon area of 0.32 mm2 . The ADC has high immunity to substrate noise and is ideal for SoC integration. APPLICATIONS General purpose data acquisition Battery monitory system Temperature monitory system | Introduction | |||||
| 2.4G PLL(UMC 28nm HPC) | By Quotes | 24.000 K μm^2 | 2.4 GHz | 28 nm | |
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| Clock output 2.4GHz Input clock 10 ~ 50MHz Current consumption: < 4mA Supply: 1.8V / 0.9V UMC 28nm HPC | Introduction | |||||
| AES Codec with 128-bit datapath | 20000 Points | 22.000 K Gates | 260 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 for high throughput applications with optimal logic resources utilization. The encryptor core accepts a 128-bit plaintext input word, and generates a corresponding 128-bit ciphertext output word using a supplied 128, 192, or 256-bit AES key. The decryptor core provides the reverse function, generating plaintext from supplied ciphertext, using the same AES key as was used for encryption. The hardware roundkey expansion logic has been designed as a discrete building block. This allows either to build a complete stand-alone AES solution, or to save logic resources by leaving the key generation process to the user. Alternatively, the roundkey expansion logic can be shared between multiple encryption/decryption cores for optimal silicon area resources utilization. The implementation is very low on latency, high speed with a simple interface for easy integration in SoC applications. | Introduction | |||||
| CAN 2.0 & CAN FD Bus Controller Core | By Quotes | 12.000 K Gates | None | None | |
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| The CAN protocol uses a multi-master bus configuration for the transfer of frames be- tween nodes of the network and manages error handling with no burden on the host processor. The core enables the user to set up economic and reliable links between vari- ous components. It appears as a memory-mapped I/O device to the host processor, which accesses the CAN core to control the transmission or reception of frames. The CAN core is easy to use and integrate, featuring programmable interrupts, data and baud rates; a configurable number of independently programmable acceptance filters; and a generic processor interface or optionally an AMBA APB, or AHB-Lite interface. It imple- ments a flexible buffering scheme, allowing fine-tuning of the core size to satisfy the requirements of each specific application | Introduction | |||||
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