Our IP is hosted on Silicon Hub, letting you download trial versions instantly. Browse our IP below, or find out more.
Overview: CMOS Image Sensors (CIS) often suffer from base noise, such as Additive White Gaussian Noise (AWGN), which deteriorates image quality in low-light environments. Traditional noise reduction methods include mask filters for still images and temporal noise data accumulation for video streams. However, these methods can lead to ghosting artifacts in sequential images due to inconsistent signal processing. To address this, this IP offers advanced noise reduction techniques and features a specific Anti-ghost Block to minimize ghosting effects. Specifications: Maximum Resolution o Image : 13MP o Video : 13MP@30fps -Input formats : YUV422–8 bits -Output formats o DVP : YUV422-8 bits o AXI : YUV420, YUV422 -8 bits-Interface o ARM® AMBA APB BUS interface for ISP system control o ARM® AMBA AXI interface for data o Direct connection to sensor stream data (DVP) Features: Base Noise Correction: AWGN reduction for improved image quality Mask Filter: Convolution-based noise reduction for still images Temporal Noise Data Accumulation: Gaussian Distribution-based noise reduction for video streams using 2 frames of images 3D Noise Reduction (3DNR): Sequential image noise reduction with Anti-ghost Block Motion Estimation and Adaptive: Suppresses ghosting artifacts during noise reduction Real-Time Processing: Supports Digital Video Port (DVP) and AXI interfaces for seamless integration Anti-Ghost Real time De-noising output
Overview: Lens distortion is a common issue in cameras, especially with wide-angle or fisheye lenses, causing straight lines to appear curved. Radial distortion, where the image is expanded or reduced radially from the center, is the most prominent type. Failure to correct distortion can lead to issues in digital image analysis. The solution involves mathematically modeling and correcting distortion by estimating parameters that determine the degree of distortion and applying inverse transformations. Automotive systems often require additional image processing features, such as de-warping, for front/rear view cameras. The Lens Distortion Correction H/W IP comprises 3 blocks for coordinate generation, data caching, and interpolation, providing de-warping capabilities for accurate image correction. Specifications: Maximum Resolution: o Image: 8MP (3840x2160) o Video: 8MP @ 60fps Input Formats: YUV422 - 8 bits Output Formats: o AXI: YUV420, YUV422, RGB888 - 8 bits Interface: o ARM® AMBA APB BUS interface for system control o ARM® AMBA AXI interface for data Features: Programmable Window Size and Position Barrel Distortion Correction Support Wide Angle Correction up to 192° De-warping Modes: o Zoom o Tilt o Pan o Rotate o Side-view Programmable Parameters: o Zoom Factor: controls Distance from the Image Plane to the Camera (Sensor)
Overview: RCCC and RCCB in ISP refer to Red and Blue Color Correction Coefficients, respectively. These coefficients are utilized in Image Signal Processing to enhance red and blue color components for accurate color reproduction and balance. They are essential for color correction and calibration to ensure optimal image quality and color accuracy in photography, video recording, and visual displays. The IP is designed to process RCCC pattern data from sensors, where green and blue pixels are substituted by Clear pixel, resulting in Red or Clear (Monochrome) format after demosaicing. It supports real-time processing with Digital Video Port (DVP) format similar to CIS output. RCCB sensors use Clear pixels instead of Green pixels, enhancing sensitivity and image quality in low-light conditions compared to traditional RGB Bayer sensors. LOTUS converts input from RCCB sensors to a pattern resembling RGB Bayer sensors, providing DVP format interface for real-time processing. Features: Maximum Resolution: 8MP (3840h x 2160v) Maximum Input Frame Rate: 30fps Low Power Consumption RCCC/RCCB Pattern demosaicing
Overview: Human eyes have a wider dynamic range than CMOS image sensors (CIS), leading to differences in how objects are perceived in images or videos. To address this, CIS and IP algorithms have been developed to express a higher range of brightness. High Dynamic Range (HDR) based on Single Exposure has limitations in recreating the Saturation Region, prompting the development of Wide Dynamic Range (WDR) using Multi Exposure images. The IP supports PWL companding mode or Linear mode to perform WDR. It analyzes the full-image histogram for global tone mapping and maximizes visible contrast in local areas for enhanced dynamic range. Specifications: Maximum Resolution: o Image: 13MP o Video: 13MP @ 60fps (Input/Output) Input Formats (Bayer): o HDR Linear Mode: Max raw 28 bits o Companding Mode: Max PWL compressed raw 24 bits Output Formats (Bayer): 14 bits Interface: o ARM® AMBA APB BUS interface for ISP system control o ARM® AMBA AXI interface for data o Video data stream interface Features: Global Tone Mapping based on histogram analysis o Adaptive global tone mapping per Input Images Local Tone Mapping for adaptive contrast enhancement Real-Time WDR Output Low Power Consumption and Small Gate Count 28-bit Sensor Data Interface
Overview: The Camera ISP IP is an Image Signal Processing (ISP) IP developed for low-light environments in surveillance and automotive applications, supporting a maximum processing resolution of 13 Mega or 8Mega Pixels (MP) at 60 frames per second (FPS). It offers a configurable ISP pipeline with features such as 18x18 2D/8x6 2D Color Shading Correction, 19-Point Bayer Gamma Correction, Region Color Saturation, Hue, and Delta L Control functions. The ISP IP enhances image quality with optimal low-light Noise/Sharp filters and offers benefits such as low gate size and memory usage through algorithm optimization. The IP is also ARM® AMBA 3 AXI protocol compliant for easy control via an AMBA 3 APB bus interface. Specifications: Maximum Resolution: o Image: 13MP/8MP o Video: 13MP @ 60fps / 8MP @ 60fps Input Formats: Bayer-8, 10, 12, 14 bits Output Formats: o DVP: YUV422, YUV444, RGB888 - 8, 10, 12 bits o AXI: YUV422, YUV444, YUV420, RGB888 - 8, 10, 12 bits Interface: o ARM® AMBA APB BUS interface for ISP system control o ARM® AMBA AXI interface for data o Direct connection to sensor stream data (DVP) o Features: Defective Pixel Correction: On-The-Fly Defective Pixel Correction 14-Bit Bayer Channel Gain Support: Up to x4 / x7.99 with Linear Algebra for Input Pixel Level Adjustment Gb/Gr Unbalance Correction: Maximum Correction Tolerance Gb/Gr Rate of 12.5% 2D Lens-Shading Correction: Supports 18x18 / 8x6 with Normal R/Gb/Gr/B Channel Shading Correction and Color Stain Correction High-Resolution RGB Interpolation: Utilizes ES/Hue-Med/Average/Non-Directional Based Hybrid Type Algorithm Color Correction Matrix: 3x3 Matrix Bayer Gamma Correction: 19 points RGB Gamma Correction: 19 points Color Enhancement: Hue/Sat/∆-L Control for R/G/B/C/M/Y Channels High-Performance Noise Reduction: For Bayer/RGB/YC Domain Noise Reduction High-Resolution Sharpness Control: Multi-Sharp Filter with Individual Sharp Gain Control Auto Exposure: Utilizes 16x16 Luminance Weight Window & Pixel Weighting Auto White Balance: Based on R/G/B Feed-Forward Method Auto Focus: 2-Type 6-Region AF Value Return
Overview: The DDR5 RCD Controller is a registering clock driver utilized in DDR5 RDIMMs and LRDIMMs. It buffers the Command/Address (CA) bus, chip selects, and clock signals between the host controller and DRAMs. Additionally, it establishes a BCOM bus to control data buffers in LRDIMMs. Key Features: Compliance with JEDEC's JESD82-511 Maximum SCL Operating speed of 12.5MHz in I3C mode DDR5 server speeds up to 4800MT/s Dual-channel configuration with 32-bit data width per channel Support for power-saving mechanisms Rank 0 & rank 1 DIMM configurations Loopback and pass-through modes BCOM sideband bus for LRDIMM data buffer control In-band Interrupt support Packet Error Check (PEC) CCC Packet Error Handling Error log register Parity Error Handling Interrupt Arbitration I2C Fast-mode Plus (FM+) and I3C Basic compatibility Switch between I2C mode and I3C Basic Clearing of Status Registers Compliance with JESD82-511 specification I3C Basic Common Command Codes (CCC) Applications: RDIMM LRDIMM AI (Artificial Intelligence) HPC (High-Performance Computing) Data-intensive applications
Overview: Cybersecurity IPs offer a range of essential security features to protect your digital assets and sensitive information. From True Random Number Generators (TRNG) to advanced encryption algorithms like AES, DES, 3DES, and cryptographic hash functions like SHA, as well as RSA for secure key exchange and digital signatures, the IPs provide a comprehensive suite of tools to safeguard your data. Key Features: True Random Number Generator (TRNG): Generates unpredictable and unbiased random numbers for cryptographic applications. Advanced Encryption Standard (AES): Provides robust encryption with symmetric key algorithms for securing data. Data Encryption Standard (DES) and Triple DES (3DES): Implement legacy encryption algorithms for data protection. Hash Functions: Includes secure cryptographic hash functions like SHA (Secure Hash Algorithm) for data integrity verification. RSA: Enables secure key exchange, encryption, and digital signatures for secure communication. These cybersecurity IPs are designed to meet the stringent security requirements of modern applications, ensuring the confidentiality, integrity, and authenticity of your data.
Overview: RGB-IR features in ISP enable the capture and processing of Red, Green, Blue, and Infrared (IR) light data in an Image Signal Processing (ISP) system. This functionality enhances image quality by extracting additional information not visible to the human eye in standard RGB images. By integrating IR and RGB data into the demosaic processing pipeline, the ISP can enhance scene analysis, object detection, and image clarity in applications such as surveillance, automotive, and security systems. Features: IR Core - 4Kx1EA: 4K Maximum Resolution: 3840h x 2160v @ 30fps IR Color Correction 3.99x support IR data Full-size output / 1/4x subsample support (Pure IR Pixel data) Only RGB-IR 4x4 pattern support IR data Crop support
Overview: The Secure Enclave IPs are Common Criteria (CC) EAL5+PP0084/PP0117 and EAL5+PP0117 certification-ready Secure Enclaves, respectively. They are available as hard macros for seamless integration into SoCs. These Secure Enclave IPs provide the highest level of security for an SoC, incorporating patented design techniques and countermeasures against side-channel and perturbation attacks to ensure robust security while minimizing power consumption. Key Features: Cryptographic Hardware Accelerators: Efficiently support standard cryptography and security operations to increase throughput while adhering to power constraints and security requirements. BootROM and Secondary Boot Loader: Manage the certified life cycle of the Secure Enclave, enforcing and assuring security from manufacturing to deployment. Proprietary IP: Based on proprietary IP that is free of 3rd party rights and royalties. Benefits: The Secure Enclave IPs offer robust security measures, efficient cryptographic support, and secure life cycle management, making them ideal for applications that require the highest levels of security and reliability. Applications: The Secure Enclave IP is versatile and suitable for a wide range of applications, including but not limited to: Secured and Certified iSIM & iUICC EMVco Payment Hardware Cryptocurrency Wallets FIDO2 Web Authentication V2X HSM Protocols Smart Car Access Secured Boot Secure OTA Firmware Updates Secure Debug Any design requiring a Secure Enclave, Secure Element, or Hardware Root of Trust protected against side-channel and perturbation fault attacks. Compliance and Support: The Secure Enclave is compliant with and ready for CC EAL5+ and EMVCo certification. It is delivered with an SDK and pre-certified CryptoLibrary and secure Boot Loader for seamless integration and enhanced security.
Overview: The Secure Boot IP is a turnkey solution that provides a secure boot facility for an SoC. It implements the Post Quantum secure Leighton-Micali Signature (LMS) as specified in NIST SP800-208. The Secure Boot IP operates as a master or slave peripheral to an Application Processor, serving as a secure enclave that securely stores keys to ensure their integrity and the integrity of the firmware authentication process. Features: Post Quantum Secure LMS Signature: Utilizes a robust Post-Quantum secure algorithm for enhanced security. Firmware Updates: Supports up to 32 thousand firmware updates with a minimal signature size of typically less than 5KBytes. SESIP Level 3 Pre-Certification: Pre-certified to SESIP Level 3 for added security assurance. RTL Delivery: Delivered as RTL for ease of integration into SoC designs. Proprietary IP: Based on proprietary IP with no 3rd party rights or royalties. Operation: The Secure Boot IP operates as a master, managing the boot process of the Application Processor to ensure that it only boots from and executes validated and authenticated firmware. The Secure Boot IP also functions as a slave peripheral, where the Application Processor requests validation of the firmware as part of its boot process, eliminating the need for managing keys and simplifying the boot process. Applications: The Secure Boot IP is versatile and suitable for a wide range of applications, including but not limited to: Wearables Smart/Connected Devices Metrology Entertainment Applications Networking Equipment Consumer Appliances Automotive Industrial Control Systems Security Systems Any SoC application that requires executing authenticated firmware in a simple but secure manner.
Overview: The Expanded Serial Peripheral Interface (xSPI) Master/Slave controller offers high data throughput, low signal count, and limited backward compatibility with legacy SPI devices. It is designed to connect xSPI Master/Slave devices in computing, automotive, Internet of Things, embedded systems, and mobile processors to various peripherals such as non-volatile memories, graphics peripherals, networking devices, FPGAs, and sensor devices. Key Features: Compliance with JEDEC standard JESD251 eXpanded SPI for Non-Volatile Memory Devices, Version 1.0 Support for Single master and multiple slaves per interface port Single Data Rate (SDR) and Double Data Rate (DDR) support Source synchronous clocking Deep Power Down (DPD) enter and exit commands Eight IO ports in standard, expandable based on system requirements Optional Data Strobe (DS) for write masking bit wide SDR transfer support Profile 1.0 Commands for non-volatile memory device management Profile 2.0 Commands for read or write data for various slave devices Applications: Consumer Electronics Defense & Aerospace Virtual Reality Augmented Reality Medical Biometrics Automotive Devices Sensor Devices
Overview: PCIe Gen6 is a high-speed, layered protocol interconnect interface supporting speeds up to 64GT/s, featuring multi-lanes and links. The Transport, Data Link, and Physical layers specified in the PCIe specification are implemented, along with PIPE interface logic connecting to PHY and AXI Bridging logic for application connectivity. Specifications: Supports PCIe Gen 6 and Pipe 5.X Specifications Core supports Flit and non-Flit Mode Lane Configurations: X16, X8, X4, X2, X1 AXI MM and Streaming supported Supports Gen1 to Gen6 modes Data rate support of 2.5 GT/s, 5 GT/s, 8 GT/s, 16 GT/s, 32 GT/s, 64 GT/s PAM support when operating at 64GT/s Encoding/Decoding Support: 8b/10b, 128b/130b, 1b/1b Supports SerDes and non-SerDes architecture Optional DMA support as plugin module Support for alternate negotiation protocol Can operate as an endpoint or root complex Lane polarity control through register Lane de-skew supported Support for L1 states and L0P Support for SKP OS add/removal and SRIS mode No equalization support through configuration Deemphasis negotiation support at 5GT/s Supports EI inferences in all modes Supports PTM, OBFF, MSI, MSIX, Power management, and all message formats
Overview: The UCIe IP supports multiple protocols (CXL/PCIe/Streaming) to connect chiplets, reducing overall development cycles for IPs and SOCs. With flexible application and PHY interfaces, The UCIe IP is ideal for SOCs and chiplets. Key Features: Supports UCIe 1.0 Specification Supports CXL 2.0 and CXL 3.0 Specifications Supports PCIe Gen6 Specification Supports PCIe Gen5 and older versions of PCIe specifications Supports single and two-stack modules Supports CXL 2.0 68Byte flit mode with Fallback mode for PCIe non-flit mode transfers Supports CXL 3.0 256Byte flit mode Supports PCIe Gen6 flit mode Configurable up to 64-lane configuration for Advanced UCIe modules and 16 lanes for Standard UCIe modules Supports sideband and Mainband signals Supports Lane repair handling Data to clock point training and eye width sweep support from transmitter and receiver ends UCIe controller can work as Downstream or Upstream Main Band Lane reversal supported Dynamic sense of normal and redundant clock and data lines activation UCIe enumeration through DVSEC Error logging and reporting supported Error injection supported through Register programming RDI/FDI PM entry, Exit, Abort flows supported Dynamic clock gang at adapter supported Configurable Options: Maximum link width (x1, x2, x4, x8, x16) MPS (128B to 4KB) MRRS (128B to 4KB) Transmit retry/Receive buffer size Number of Virtual Channels L1 PM substate support Optional Capability Features can be Configured Number of PF/VFDMA configurable Options AXI MAX payload size Variations Multiple CPI Interfaces (Configurable) Cache/memory configurable Type 0/1/2 device configurable
Overview: The Multi-Protocol Accelerator IP is a versatile technology designed to support low latency and high bandwidth accelerators for efficient CPU-to-device and CPU-to-memory communication. It also enables switching for fan-out to connect more devices, memory pooling for increased memory utilization efficiency, and provides memory capacity with support for hot-plug, security enhancements, persistent memory support, and memory error reporting. Key Features: CXL 3.0 Support: Compliant with CXL spec V3.X/V2.X PCIe Compatibility: Supports PCIe spec 6.0/5.0 CPI Interface: Support for CPI Interface AXI Interface: Configurable AXI master, AXI slave Bus Support: PIPE/FLEX bus, Lane x1,x2,x4,x8,x16 Protocol Support: Gen3, Gen4, Gen5 & Gen6, Fallback Mode Register Checks: Configuration and Memory Mapped registers Dual Mode: Supports Dual Mode operation Transfer Support: HBR/PBR & LOpt Transfers, Standard Cache and Mem Transfers CXL Support: Can function as both CXL host and device Data Transfer: Supports Standard IO, 68Byte Flit, and 256Byte Flit Transfers FlexBus Features: FlexBus Link Features, ARB/MUX, ARB/MUX Bypass Optimization: Latency Optimization, Credit Return Forcing, Empty Flits (Latency Optimized) Power Management: Supports Power Management features Enhancements: CXL IDE, RAS Features, Poison & Viral Handling, MLD/SLD Testing: Compliance Testing and Error Scenarios support
Overview: The MIPI CSI-2 (Camera Serial Interface) defines an interface between a peripheral device (camera) and host processor (application engine) for mobile applications. It offers the mobile industry a standard, robust, scalable, low-power, high-speed, and cost-effective interface that supports a wide range of imaging solutions for mobile devices. Key Features: Compliance with MIPI-CSI-2 version 3.0 Compliance with C-PHY 2.0 for MIPI CSI-2 Version 3.0 Compliance with D-PHY 2.5 for MIPI CSI-2 Version 3.0 Compatibility with I2C and I3C (SDR, DDR) for CCI interface Support for C-PHY 2.0, D-PHY 2.5, A-PHY, M-PHY with configurable PHY layer Processor Interfaces: AHB Lite/APB/AXI for configuration Lane Merging Function for consolidating packet data in CSI-2 Receiver De-skew detection in D-PHY and sync word detection in C-PHY Pixel Formats Supported: YUV, RGB, and RAW data Virtual Channels: 16 for D-PHY, 32 for C-PHY Error detection, interleaving, scrambling, and descrambling support Byte to pixel conversion in LLP layer Applications: Imaging Surveillance Gaming Sensor devices Internet of Things (IoT) Wearable devices Virtual Reality Augmented Reality Automotive Systems
Overview: The MIPI I3C Controller IP Core is fully compliant with the latest I3C specification, offering high bandwidth and scalability for integrating multiple sensors into mobile, automotive, and IoT system-on-chips (SoCs). This controller support in-band interrupts within the 2-wire interface, reducing pin count, simplifying board design, and lowering power and system costs. Backward compatibility with I2C ensures future-proof designs, and the controller's operating modes enable efficient connectivity for systems with multiple ICs and sensors on a single I3C bus. The ARM® AMBA® Advanced High-Performance Bus (AHB) facilitates seamless integration of the IP into the SoC. Key Features: Compliance with MIPI-I3C Basic v1.0 Backward compatibility with I2C Two-wire serial interface up to 12.5MHz using Push-Pull Dynamic and Static Addressing support Single Data Rate messaging (SDR) Broadcast and Direct Common Command Code (CCC) Messages support In-Band Interrupt capability Hot-Join Support Applications: Consumer Electronics Defense Aerospace Virtual Reality Augmented Reality Medical Biometrics (Fingerprints, etc.) Automotive Devices Sensor Devices
Overview: The MIPI DSI Transmitter IP is designed to transmit data to the host processor, providing the mobile industry with a standard, robust, scalable, low-power, high-speed, and cost-effective interface that supports a wide range of imaging solutions for mobile devices. Key Features: Compliance with MIPI-DSI-2 version 2.0 Compliance with C-PHY version 2.0 for DSI-2 Version-2 Compliance with D-PHY version 1.2 for DSI-2 Version-2.0 Compliance with D-PHY version 2.0 for DSI-2 Version-2.0 Compliance with D-PHY version 3.0 for DSI-2 Version-2.0 Compliance with MIPI SDF specification Compliance with DBI-2 and DPI-2 Pixel to Byte conversion support from Application layer to LLP layer Support for Command Mode and Video Mode Continuous clock behavior in clock lane for D-PHY physical layer De-skew sequence pattern for video mode support Lane Distribution Function for distributing packet bytes across N-Lanes Connectivity with two, three, or four DSI Receivers HS mode and Escape mode support for transmission of Packets in both C-PHY and D-PHY Symbol slip detection code and sync symbol insertion in C-PHY physical layer Target Applications: Imaging Surveillance Gaming Sensor devices Internet of Things (IoT) Wearable devices Virtual Reality Augmented Reality Automotive Systems
Our Expanded Serial Peripheral Interface (JESD251) Slave controller offers high data throughput, low signal count, and limited backward compatibility with legacy Serial Peripheral Interface (SPI) devices. It is used to connect xSPI Master devices in computing, automotive, Internet of Things, embedded systems, and mobile system processors to non-volatile memories, graphics peripherals, networking peripherals, FPGAs, and sensor devices. Features • Compliant with JEDEC standard JESD251 expanded Serial Peripheral Interface (xSPI) for Non-Volatile Memory Devices, Version 1.0. • Supports Single Data Rate (SDR) and Double Data Rate (DDR). • Supports source synchronous clocking. • Supports data transfer rates up to: o 400MT/s (200MHz Clock) o 333MT/s (167MHz Clock) o 266MT/s (133MHz Clock) o 200MT/s (100MHz Clock) • Supports Deep Power Down (DPD) enter and exit commands. • Standard support for eight IO ports, with the possibility to increase IO ports based on system performance requirements. • Optional support for Data Strobe (DS) for timing reference. • Supports 1-bit wide SDR transfer. • Supports Profile 1.0 commands to manage nonvolatile memory devices. • Supports Profile 2.0 commands for reading or writing data for any type of slave device. • Compatible with non-volatile memory arrays such as NOR Flash, NAND Flash, FRAM, and nvSRAM. • Compatible with volatile memory arrays such as SRAM, PSRAM, and DRAM. • Supports register-mapped input/output functions. • Supports programmable function devices such as FPGAs. Application • Consumer Electronics. • Defence & Aerospace. • Virtual Reality. • Augmented Reality. • Medical. • Biometrics (Fingerprints, etc). • Automotive Devices. • Sensor Devices. Deliverables • Verilog Source code. • User Guide. • IP Integration Guide. • Run and Synthesis script. • Encrypted Verification Testbench Environment. • Basic Test-suite.
Overview: The SPD5 Hub controller IP is designed to interface with the I3C/I2C Host Bus, allowing for the isolation of local devices such as Temperature Sensors (TS) from the master host bus. It features a Two-wire serial interface with SCL and SDA busses. Key Features: Compliance with JEDEC's JESD300-5 Support for speeds up to 12.5MHz Bus Reset functionality SDA arbitration support Enabled Parity Check Support for Packet Error Check (PEC) Switch between I2C and I3C Basic Mode Default Read address pointer Mode Write and read operations for SPD5 Hub with or without PEC In-band Interrupt (IBI) support Write Protection for NVM memory blocks Arbitration for Interrupts Clearing of Device Status and IBI Status Registers Error handling for Packet Error Check and Parity Errors Common Command Codes (CCC) for I3C Basic Mode Dynamic IO Operation Mode Switching Bus Clear and Bus Reset capabilities SPD5 Command features for NVM memory and Register Space Read and Write access to NVM memory Support for Offline Tester operation Applications: DDR5 DIMM Application Environment DDR5 NVDIMM Application Environment Automotive Devices Memory Devices Power Management Devices Defense/Aerospace/Customer Electronics
Our Expanded Serial Peripheral Interface (JESD251) Master controller features a low signal count and high data bandwidth, making it ideal for use in computing, automotive, Internet of Things, embedded systems, and mobile system processors. It connects multiple sources of Serial Peripheral Interface (xSPI) slave devices, including nonvolatile memories, graphics peripherals, networking peripherals, FPGAs, and sensor devices. Features • Compliant with JEDEC standard JESD251 expanded Serial Peripheral Interface (xSPI) for Non-Volatile Memory Devices, Version 1.0. • Supports a single master and multiple slaves per interface port. • Supports Single Data Rate and Double Data Rate. • Supports source synchronous clocking. • Supports data transfer rates up to: o 400MT/s (200MHz Clock) o 333MT/s (167MHz Clock) o 266MT/s (133MHz Clock) o 200MT/s (100MHz Clock) • Supports Deep Power Down (DPD) enter and exit commands. • Standard support for eight IO ports, with the possibility to increase IO ports based on system performance requirements. • Optional support for Data Strobe (DS) for writemasking. • Supports 1-bit wide SDR transfer. • Supports Profile 1.0 commands to manage nonvolatile memory devices. • Supports Profile 2.0 commands to read or writedata for any type of slave device. • Compatible with non-volatile memory arrays such as NOR Flash, NAND Flash, FRAM, and nvSRAM. • Compatible with volatile memory arrays such as SRAM, PSRAM, and DRAM. • Supports register-mapped input/output functions. • Supports programmable function devices such as FPGAs. Application • Consumer Electronics. • Defence & Aerospace. • Virtual Reality. • Augmented Reality. • Medical. • Biometrics (Fingerprints, etc). • Automotive Devices. • Sensor Devices. Deliverables • Verilog Source code. • User Guide. • IP Integration Guide. • Run and Synthesis script. • Encrypted Verification Testbench Environment. • Basic Test-suite.
Overview: The Power Management IC (PMIC) is specifically designed for DDR5 RDIMM, DDR5 LRDIMM, and DDR5 NVDIMM applications. It includes switching and LDO regulators to efficiently manage power distribution. The PMIC utilizes a MIPI-I3C Interface to select appropriate power settings for various application environments and is capable of operating at speeds up to 12.5MHz. Key Features: Maximum Operating speed of 12.5MHz Flexible Open-Drain IO (I2C) and Push-Pull (I3C) IO Support Multi-Time Programmable Non-Volatile Memory Interface Programmable and DIMM-specific registers for customization Error log registers for tracking Packet Error Check (PEC) and Parity Error Check functions Bus Reset function Support I3C Basic mode In-Band Interrupt (IBI) support Write, read, and default read operations in I2C mode Error handling for PEC, Parity errors, and CCC errors I3C Basic Common Command Codes (CCC) support Applications: DDR5 DIMM Application Environment DDR5 NVDIMM Application Environment Automotive Devices Memory Devices Power Management Devices Defense/Aerospace/Customer Electronics
PCIE is a layered protocol high speed interconnect interface supporting speeds up to 128Gbps and multi lanes and links. The layers speci_ied in PCIE speci_ication Transport, Datalink, Physical layers (digital packet) are implemented in PRIMEXPRESS IP along with PIPE interface logic connecting to PHY and AXI Bridging logic to connect to applications. Features: • Supports PCIE Gen 7 draft Spec. • Supports Pipe 6.X Spec. • PCIE Gen 7.0 Core supports Flit and non – Flit Mode. • Supports X16, X8, X4, X2, X1 Lane Configuration. • AXI MM and Streaming supported. • Supports Gen 1, Gen 2, Gen 3, Gen 4, Gen 5, Gen 6, Gen 7 modes. • Data rate support of 2.5 Gbps, 5 Gbps, 8 Gbps, 16 Gbps, 32 Gbps, 64 Gbps, 128 Gbps. • PAM support when operating at 64Gbps/ 128Gbps. • 8b/10b,128b/130b,1b/1b encoding , decoding support. • Supports EP & RC. • Supports serdes and non – serdes architecture. • Optional DMA support as plugin module. • Support for alternate negotiation protocol. • Lane polarity thru register control. • Lane deskew supported. • Support for L1 states. • L0P Supported. • SKP OS add/removal. • SRIS mode supported. • No equalization support thru configuration. • Deemphasis negotiation support at 5GT/s. • EI inferences in all modes. • PTM, OBFF, MSI, MSIX, Power management and all message format supports.
PCIE is a layered protocol high speed interconnect interface supporting speeds up to 128Gbps and multi lanes and links. The layers speci_ied in PCIE speci_ication Transport, Datalink, Physical layers (digital packet) are implemented in PRIMEXPRESS IP along with PIPE interface logic connecting to PHY and AXI Bridging logic to connect to applications. Features: • Supports PCIE Gen 7 draft Spec. • Supports Pipe 6.X Spec. • PCIE Gen 7.0 Core supports Flit and non – Flit Mode. • Supports X16, X8, X4, X2, X1 Lane Configuration. • AXI MM and Streaming supported. • Supports Gen 1, Gen 2, Gen 3, Gen 4, Gen 5, Gen 6, Gen 7 modes. • Data rate support of 2.5 Gbps, 5 Gbps, 8 Gbps, 16 Gbps, 32 Gbps, 64 Gbps, 128 Gbps. • PAM support when operating at 64Gbps/ 128Gbps. • 8b/10b,128b/130b,1b/1b encoding , decoding support. • Supports serdes and non – serdes architecture. • Optional DMA support as plugin module. • Support for alternate negotiation protocol. • Lane polarity thru register control. • Lane deskew supported. • Support for L1 states. • L0P Supported. • SKP OS add/removal. • SRIS mode supported. • No equalization support thru configuration. • Deemphasis negotiation support at 5GT/s. • EI inferences in all modes. • PTM, OBFF, MSI, MSIX, Power management and all message format supports.
PCIE is a layered protocol high speed interconnect interface supporting speeds up to 128Gbps and multi lanes and links. The layers speci_ied in PCIE speci_ication Transport, Datalink, Physical layers (digital packet) are implemented in PRIMEXPRESS IP along with PIPE interface logic connecting to PHY and AXI Bridging logic to connect to applications. Features: • Supports PCIE Gen 7 Spec. • Supports Pipe 6.X Spec. • PCIE Gen 7.0 Core supports Flit and non – Flit Mode. • Supports X16, X8, X4, X2, X1 Lane Configuraon. • AXI MM and Streaming supported. • Supports Gen 1, Gen 2, Gen 3, Gen 4, Gen 5, Gen 6, Gen 7 modes. • Data rate support of 2.5 Gbps, 5 Gbps, 8 Gbps, 16 Gbps, 32 Gbps, 64 Gbps, 128 Gbps. • PAM support when operating at 64Gbps/ 128Gbps. • 8b/10b,128b/130b,1b/1b encoding , decoding support. • Supports serdes and non – serdes architecture. • Oponal DMA support as plugin module. • Support for alternate negoaon protocol. • Lane polarity thru register control. • Lane deskew supported. • Support for L1 states. • L0P Supported. • SKP OS add/removal. • SRIS mode supported. • No equalization support thru configuraon. • Deemphasis negotiation support at 5GT/s. • EI inferences in all modes. • PTM, OBFF, MSI, MSIX, Power management and all message format supports.
Overview: The MIPI CSI-2 (Camera Serial Interface) Transmitter IP establishes an interface between a peripheral device (camera) and host processor (application engine) for mobile applications. It offers the mobile industry a standard, robust, scalable, low-power, high-speed, and cost-effective interface that caters to a wide range of imaging solutions for mobile devices. Key Features: Compliance with MIPI-CSI-2 version 3.0 Compliance with C-PHY 2.0 for MIPI CSI-2 Version 3.0 Compliance with D-PHY 2.5 for MIPI CSI-2 Version 3.0 Compatibility with I2C and I3C (SDR, DDR) for CCI interface Pixel to Byte conversion support from Application layer to LLP layer Continuous clock behavior in clock lane for D-PHY physical layer De-skew sequence pattern in Data Lane Module Lane Distribution Function for distributing packet bytes across N-Lanes Sync word insertion through PPI command in C-PHY physical layer Insertion of Filler bytes in LLP layer for packet footer alignment Setting specific bits in packet header Defining frame blanking period Seed selection in scrambler and de-scrambler by Sync word Support for C-PHY/D-PHY/A-PHY/M-PHY with one PHY layer configuration Target Applications: Imaging Surveillance Gaming Sensor devices Internet of Things (IoT) Wearable devices Virtual Reality Augmented Reality Automotive Systems
Join the world's most advanced semiconductor IP marketplace!
It's free, and you'll get all the tools you need to evaluate IP, download trial versions and datasheets, and manage your evaluation workflow!