All IPs > Multimedia > CSC
In the Multimedia domain, the Color Space Converter (CSC) is a crucial piece of semiconductor IP that facilitates the transformation of digital color information from one color space to another. This capability is vital in various applications, such as video streaming, gaming, digital displays, cameras, and video editing software. With the multitude of devices and display technologies available today, efficient color space conversion ensures that media content is accurately reproduced with vibrant and true-to-life colors across different platforms and devices.
The process of color space conversion involves translating the RGB color space, which is commonly used in electronic displays and cameras, into other formats like YUV or YCbCr, which are often used for video compression and broadcast. Such conversions are essential for optimizing the visual quality of media during transmission, storage, and display. High-quality CSC semiconductor IPs ensure minimal error and distortion during this conversion process, maintaining the integrity and clarity of the original media content.
Semiconductor IPs designed for color space conversion are particularly significant for developers and manufacturers in the multimedia industry. These IPs can be integrated into System on Chip (SoC) architectures for various multimedia devices, aiding in energy efficiency and performance enhancement. The IPs support real-time processing capabilities, which are critical for applications like live video feeds, high-definition gaming, and augmented reality, where any delay or lapse in color accuracy can compromise the user experience.
Our category of Color Space Converter IPs at Silicon Hub includes a diverse range of solutions to meet different application requirements. Whether you're developing a new display technology, a camera system, or multimedia processing software, these IPs can provide the necessary tools for seamless color management. Explore our offerings to find the right color space conversion technology for your next multimedia project, thereby ensuring outstanding quality and consistency in digital color representation.
The KL730 is a third-generation AI chip that integrates advanced reconfigurable NPU architecture, delivering up to 8 TOPS of computing power. This cutting-edge technology enhances computational efficiency across a range of applications, including CNN and transformer networks, while minimizing DDR bandwidth requirements. The KL730 also boasts enhanced video processing capabilities, supporting 4K 60FPS outputs. With expertise spanning over a decade in ISP technology, the KL730 stands out with its noise reduction, wide dynamic range, fisheye correction, and low-light imaging performance. It caters to markets like intelligent security, autonomous vehicles, video conferencing, and industrial camera systems, among others.
The KL530 represents a significant advancement in AI chip technology with a new NPU architecture optimized for both INT4 precision and transformer networks. This SOC is engineered to provide high processing efficiency and low power consumption, making it suitable for AIoT applications and other innovative scenarios. It features an ARM Cortex M4 CPU designed for low-power operation and offers a robust computational power of up to 1 TOPS. The chip's ISP enhances image quality, while its codec ensures efficient multimedia compression. Notably, the chip's cold start time is under 500 ms with an average power draw of less than 500 mW, establishing it as a leader in energy efficiency.
The PDM-to-PCM Converter from Archband Labs leads in transforming pulse density modulation signals into pulse code modulation signals. This converter is essential in applications where high fidelity of audio signal processing is vital, including digital audio systems and communication devices. Archband’s solution ensures accurate conversion, preserving the integrity and clarity of the original audio. This converter is crafted to seamlessly integrate with a wide array of systems, offering flexibility and ease-of-use in various configurations. Its robust design supports a wide range of input frequencies, making it adaptable to different signal environments. The PDM-to-PCM Converter also excels in minimizing latency and reducing overhead processing times. It’s engineered for environments where precision and sound quality are paramount, ensuring that audio signals remain crisp and undistorted during conversion processes.
The EZiD211, also known as Oxford-2, is a leading-edge demodulator and modulator developed by EASii IC to facilitate advanced satellite communications. It embodies a sophisticated DVB-S2X wideband tuner capable of supporting LEO, MEO, and GEO satellites, integrating proprietary features like Beam Hopping, VLSNR, and Super Frame applications. With EZiD211 at the helm, satellite communications undergo a transformation in efficiency and capacity, addressing both current and future demands for fixed data infrastructures, mobility, IoT, and M2M applications. Its technological forefront facilitates seamless operations in varied European space programs, validated by its full production readiness. EZiD211's design offers a unique capability to manage complex satellite links, enhance performance, and ensure robust and reliable data transmission. EASii IC provides comprehensive support through evaluation boards and samples, allowing smooth integration and testing to meet evolving satellite communication standards.
The C100 IoT chip by Chipchain is engineered to meet the diverse needs of modern IoT applications. It integrates a powerful 32-bit RISC-V CPU capable of reaching speeds up to 1.5GHz, with built-in RAM and ROM to facilitate efficient data processing and computational capabilities. This sophisticated single-chip solution is known for its low power consumption, making it ideal for a variety of IoT devices. This chip supports seamless connectivity through embedded Wi-Fi and multiple transmission interfaces, allowing it to serve broad application areas with minimal configuration complexity. Additionally, it boasts integrated ADCs, LDOs, and temperature sensors, offering a comprehensive toolkit for developers looking to innovate across fields like security, healthcare, and smart home technology. Notably, the C100 simplifies the development process with its high level of integration and performance. It stands as a testament to Chipchain's commitment to providing reliable, high-performance solutions for the rapidly evolving IoT landscape. The chip's design focuses on ensuring stability and security, which are critical in IoT installations.
The DSC Decoder by Trilinear Technologies delivers high-performance video compression capabilities for applications demanding real-time display stream processing. Encapsulated in robust silicon-proven IP, the decoder supports Display Stream Compression (DSC) standards, allowing for efficient compression and decompression of high-definition video streams. This ensures seamless video quality while optimizing the use of data transmission channels and saving bandwidth. A vital component of modern multimedia systems, the DSC Decoder is particularly valuable in industries where image quality and transmission efficiency are critical, such as in broadcasting, telecommunications, and advanced surveillance systems. By implementing industry-standard interfaces for configuration and operation, the decoder achieves smooth interoperability with a wide range of host systems and devices, simplifying its integration into existing digital infrastructures. Trilinear Technologies' DSC Decoder is optimized for low power consumption without sacrificing performance. This focus on energy efficiency makes it ideal for portable and battery-powered devices that demand prolonged operational times without frequent recharging. Its real-time decoding capability ensures that even high-definition streams up to 16K can be managed effectively, providing high-detail video output in a variety of formats and resolutions. The integration of the DSC Decoder is facilitated by detailed support documentation and software stacks that make it easier for developers to incorporate the IP into systems with varied architectural foundations. Whether deployed in consumer electronics or professional AV installations, this decoder ensures high-quality video output with reduced latency, meeting the demands of modern digital workflows and multimedia needs.
The DSC Encoder from Trilinear Technologies sets the standard for real-time video compression within digital display and broadcast technologies. Supporting VESA’s Display Stream Compression criteria, this encoder facilitates the efficient compression of high-definition video streams, which is critical for reducing bandwidth usage while maintaining video quality across transmission channels in advanced video systems. Trilinear’s encoder is ideal for numerous applications, ranging from consumer electronics to professional AV systems, where ensuring high-quality video output is paramount. Its robust functionality enables it to handle streams with precision and maintain visual integrity, making it essential for systems that require high-efficiency video compression such as gaming consoles, digital TV, and mobile devices. The DSC Encoder offers a high degree of configurability, providing developers with the flexibility to adapt it to various system requirements. It is equipped with industry-standard interfaces, allowing straightforward integration into existing infrastructure, ensuring compatibility and operational efficiency across different platforms. This versatility makes it well-suited for use in SoC designs and FPGA implementations, broadening its applicability across various technological landscapes. Featuring comprehensive software support and detailed user documentation, Trilinear’s DSC Encoder simplifies the integration process into complex systems, ensuring that developers can tap into its full range of capabilities with ease. Its real-time processing power and optimized energy consumption profile make it a reliable choice for cutting-edge digital video applications, reflecting Trilinear’s commitment to advancing multimedia technology.
The Camera PHY Interface for Advanced Processes is an advanced interface solution supporting various transmission standards for high-speed data transfer in image sensor applications. It offers robust performance by integrating sub-LVDS, MIPI D-PHY, and HiSPi protocols, among others, ensuring versatile compatibility with advanced semiconductor manufacturing processes. This interface IP is instrumental in facilitating the seamless integration of CMOS image sensors in high-resolution and high-frame-rate cameras, enabling superior image capture quality and efficiency. The Camera PHY Interface is engineered to support high-speed data rates up to 5Gbps, making it suitable for applications requiring rapid data transmission and processing capabilities, such as in professional photography or high-end surveillance equipment. The use of advanced process nodes ensures that the interface maintains its high performance while supporting low power consumption, which is critical for portable and power-sensitive applications. Incorporating this IP within camera systems enhances the overall data throughput and integrity, minimizing latency and ensuring real-time image processing. It is particularly beneficial in devices that demand quick image data transmission without degradation, paving the way for smoother video recording and image capturing experiences. The adaptability of this PHY interface to various standards and process variations further enhances its applicability across multiple platforms and use cases, promoting a high degree of design flexibility.
The JPEG Encoder IP by Section5 is a robust compression tool designed to facilitate high-quality image and video encoding. Compliant with ITU standards, it supports up to 12-bit depths, offering flexibility for various applications. This encoder is particularly valued in machine vision and network streaming, where its low power consumption and minimal latency make it ideal for high-performance environments. Its dual-pipe architecture enhances its efficiency, allowing for simultaneous high-quality encoding streams, such as YUV422 up to 1280x720 at 60 frames per second. This encoder is versatile, supporting a range of pixel depths and ensuring high compression efficiency with minimal data loss. It is especially optimized for use in FPGA environments, designed to work without the need for external RAM, further reducing its power footprint. The encoder's architecture also supports Ethernet transmission, making it incredibly flexible for different applications, from camera solutions to embedded systems. Section5’s JPEG Encoder is highly customizable, with support for various configurations and different bitstreams compatible with projects requiring either stand-alone or fully integrated solutions. Developers can leverage this IP for creating robust solutions in fields such as security, video conferencing, and broadcast, benefiting from its superior image quality and reliability.
SMPTE ST 2110 is a sophisticated protocol designed to facilitate the transport of media over IP networks, commonly used in broadcast and professional AV settings. This IP solution enhances the ability to transmit a variety of media types such as video, audio, and ancillary data via IP, leveraging the modularity to achieve optimal resource efficiency. Supporting an array of sub-standards, including uncompressed video (ST 2110-20) and compressed video (ST 2110-22), this IP bolsters transmission quality and reliability, ensuring consistent system timing and seamless traffic shaping. With its robust support for both gateway and synthetic essence operations, SMPTE ST 2110 enables effective integration with legacy systems and ensures a future-ready setup for the transmission of high-quality media content over IP. The core is highly configurable, allowing users to tailor features according to specific broadcast requirements while maintaining resource efficiency. By utilizing only necessary RTL logic, it minimizes overhead while offering a versatile solution for both professional AV equipment and broadcast systems. Integrated into an ecosystem of proven interoperable standards, this IP ensures smooth transitions between digital and traditional workflows, establishing itself as a pivotal component in AV-over-IP infrastructures. The design includes capabilities to handle various media types, making it adaptable to different operational needs. Nextera’s SMPTE ST 2110 IP is supported by a comprehensive reference design project, inclusive of necessary drivers and control software, enabling rapid system prototyping and deployment. Customers benefit from a well-documented setup that fosters swift development cycles and reduces time-to-market, underpinned by Nextera's emphasis on sustained performance and innovation within IP media experiences.
The DVB-C Modulator is specifically designed to perform modulations for head-end video and broadband data transmission systems, such as Cable Modem Termination Systems (CMTS). This modulator core is optimized for use in various cable modem test equipment and supports both point-to-point (PTP) and point-to-multipoint microwave radio links. It boasts compliance with the J83 standard modulation schemes, enhancing its flexibility and usability across different platforms.
The DVB-S2X Wideband LDPC Decoder is a powerful FEC core decoder for Digital Video Broadcasting via Satellite. It implements extensions to the DVB-S2 design for better performance and efficiency as well as robust service availability. Features include irregular parity check matrix, layered decoding, minimum sum algorithm, and soft decision decoding. The BCH decoder works on GF(2^m) where m=16 or 14 and corrects up to t errors, with t being 8, 10, or 12. It is ETSI EN 302 307-1 V1.4.1 (2014-11) compliant. Other key features include medium codeword length, extra code rates for finer gradation, support for 64, 128, 256 APSK, and operation in very low SNR environments down to -10dB with wideband support. This results in improved performance, efficiency with respect to Shannon’s limit, finer gradation of code rate and SNR, and enables very high data rates and maximum service availability at highest efficiency, along with cross-layer optimization. Deliverables include synthesizable Verilog, system model in Matlab, Verilog test benches, and documentation. A comprehensive DVB-S2X Wideband LDPC/BCH decoder datasheet is available under NDA.
The Universal QAM/PSK Modulator is an adaptable core designed for broadband point-to-point and point-to-multipoint applications. It delivers versatile modulation capabilities that are compatible with IEEE 802.16.x Wireless MAN-SC and 802.15.3 Wireless PAN standards. By supporting varied applications, this modulator ensures reliable and efficient wireless communication across diverse platforms. Its robust framework enables seamless modulation processes suited for both small-scale and extensive network operations, optimizing wireless signal transmission.
The ISDB-T Modulator delivers robust capabilities for both professional TV networks and custom point-to-point radio links. This modulator core is fully compliant with ARIB STD-B31 and ABNT NBR 15601, ensuring compatibility across a broad range of broadcasting applications. Its adaptable framework makes it suitable for diverse broadcast needs, facilitating the efficient transmission of digital television signals. Through this, broadcasters can achieve a more reliable and consistent service quality across different market segments.
The DVB-S2 Modulator is engineered to accommodate both DVB-S2 and DVB-S2X satellite forward-link specifications. This high-performance modulator core supports (A)PSK modulation schemes and is particularly suitable for both broadcasting and interactive applications. Its design is focused on delivering advanced functionalities while ensuring compliance with dynamic satellite communication standards. This makes it well-suited for a variety of professional and commercial telecommunications applications. The modulator is ideal for delivering superior broadcast experiences with increased efficiency and reliability.
The DVB-Satellite Modulator is a high-performance modulator core designed to adhere to DVB-S, DSNG, DVB-S2, and DVB-S2X satellite forward-link specifications. This versatile modulator core is engineered for both broadcasting and interactive applications, accommodating a variety of modulation schemes including (A)PSK. Its robust framework is capable of delivering efficient and reliable operations in challenging satellite communication environments. The modulator's design prioritizes support for advanced satellite communication standards, ensuring its place in future-ready satellite systems.
Designed for maximum compatibility and efficiency, the ATSC 8-VSB Modulator serves both professional TV network applications and custom point-to-point radio links. Its comprehensive compliance with ATSC A/53 8-VSB standards guarantees reliable performance across multiple broadcast scenarios. The modulator's versatile design supports varied operational environments, making it indispensable for broadcasters who require versatile and robust transmission solutions. Its emphasis on delivering flawless signal integrity ensures top-notch broadcast quality for diverse applications.
The DVB-T2 Demodulator and LDPC/BCH Decoder is a comprehensive system designed for use with an RF tuner and an analog to digital converter. It features compliance with DVB-T2 EN302 755 V1.2.1, Rev.9 standards and supports flexible channel bandwidths ranging from 1.7 MHz to 10 MHz. The system boasts capabilities like IF input support, SISO operation, sampling frequency offset tracking and compensation, carrier frequency offset detection and correction, and support for BPSK, QPSK, and QAM constellations (16, 64, 256). It includes a layered Min-Sum LDPC decoder and a BCH decoder, with parallel and serial MPEG outputs. The demodulator operates with a single external clock and can be externally configured via an SPI port, enhancing its flexibility and integration into set-top boxes and digital TV receivers.
Focused on meeting the ETSI DVB-CID carrier identification standard (EN103129), the DVB-CID Modulator integrates both modulation and channel coding functionalities into a single cohesive core. This integration is aimed at addressing specific carrier identification requirements within satellite communication systems. By streamlining these processes, the modulator enhances operational efficiencies while ensuring adherence to key industry standards. The DVB-CID Modulator effectively supports sophisticated satellite communication systems demanding reliable carrier identification capabilities.
The DVB-T2 Modulator stands out with its powerful FPGA or ASIC implementation, designed to perform efficient modulation as per the DVB-T2 ETSI EN302 755 standards. This comprehensive solution encompasses all necessary functions to facilitate high-performance terrestrial broadcasts. The modulator is crafted for use in a range of broadcast networks, offering flexibility and adaptability in its application. This makes it a go-to solution for broadcasters aiming to leverage the power of DVB-T2 technology to deliver superior terrestrial broadcast services.
The Multi-channel ATSC 8-VSB Modulator enhances broadcasting flexibility by supporting multiple channels within ATSC A/53 8-VSB standards. Tailored to meet professional TV network and custom point-to-point radio link needs, this modulator core facilitates complex broadcast operations. It enables seamless integration and high-quality signal transmission across varied operational environments. By efficiently managing multiple channels, it empowers broadcasters to optimize signal delivery and enhance their overall transmission capabilities.
The Multi-channel DVB-C Modulator expands on the versatility of its predecessor by supporting multiple channels simultaneously. It is targeted at head-end video and broadband data transmissions systems, including Cable Modem Termination Systems (CMTS), and is also effective for use in cable modem test equipment. Like the single-channel version, it is suited for point-to-point (PTP) or point-to-multipoint microwave radio links, making it a robust choice for dynamic broadcast environments. Its ability to process multiple channels helps in streamlining operations within complex broadcast systems.
The Display Compression Encoder and Decoder offered by BTREE is a comprehensive solution aimed at enhancing display data management through efficient compression and decompression processes. This product is engineered to significantly reduce the amount of data required for image transmission, which is crucial for improving bandwidth utilization and minimizing latency in visual computing applications. With an eye towards maintaining high fidelity, these encoder and decoder technologies preserve the quality of the original image during the compression and decompression cycles. This ensures that users experience seamless visual output without perceptible loss of quality. As a result, this solution is particularly beneficial for applications in gaming, video conferencing, and large-scale digital displays, where rapid and efficient data handling is critical. The Display Compression technology is based on advanced algorithms that are capable of handling high-resolution and high-frame-rate content, ensuring that it meets the demands of modern consumer and professional electronic devices. The capability to reduce power consumption while maintaining performance makes it ideal for a wide array of devices, from portable electronics to high-end visual systems.
The Orion family of pattern projectors from Metalenz represents a leap forward in optical projection technology by utilizing meta-optics to achieve compactness and precision. These projectors are designed to meet the needs of various applications, particularly those requiring high-quality pattern projection, such as AR/VR systems and industrial automation tools. Orion projectors distinguish themselves by using metasurface optics, which provide a smaller form factor and require less power than conventional optical systems. This capability makes them ideal for integration into portable or compact consumer devices, delivering excellent projection performance without the bulkiness of traditional systems. By implementing metasurface technology, the Orion projectors can emit complex light patterns with improved energy efficiency, ensuring that the systems using them can operate longer on battery power and deliver more vivid and precise projections. This innovation is critical in enhancing the realism and functionality of next-generation display and sensing technologies.
Designed for the seamless transmission of compressed video over Serial Digital Interface (SDI), the SDI Mapping IP Cores enable the transport of high-definition video in both legacy and modern broadcast setups. This technology supports the integration of JPEG XS compressed video into existing SDI frameworks, offering broadcasters a way to maintain high-quality video transmissions while adapting to newer video standards.\n\nThe SDI Mapping IP Cores are tailored to ensure efficient bandwidth usage without compromising video quality. They enable the support of various SDI standards and resolutions up to 8K, making them an ideal choice for broadcasters looking to future-proof their video infrastructure. By leveraging advanced compression techniques, these cores facilitate significantly reduced data rates, enabling smoother and more efficient video transport over established SDI networks.\n\nOne of the core benefits of the SDI Mapping IP Cores is their ability to diminish latency to negligible levels, a vital requirement for live broadcast environments where timing is crucial. By supporting both progressive and interlaced video formats, these cores accommodate a wide range of video production needs while ensuring that output remains consistent and reliable, regardless of data throughput challenges.\n\nAdditionally, these IP cores offer simple integration interfaces and configurable settings, ensuring they can be tailored to fit specific broadcasting conditions. With an emphasis on maintaining robustness and minimal resource usage, the SDI Mapping IP Cores stand as a key component for broadcasters aiming to innovate within traditional broadcast setups while embracing modern video compression standards.
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