All IPs > Security IP > Embedded Security Modules
In today's interconnected technological landscape, the security of embedded systems has emerged as a crucial challenge. This is where Embedded Security Modules (ESMs) in semiconductor IPs play a pivotal role. These modules are specialized components integrated into chips, offering enhanced protection against a variety of threats including unauthorized access, data breaches, and malicious attacks. By embedding security at the silicon level, these IPs provide a hardware root of trust, ensuring that the integrity, confidentiality, and authenticity of data and communications are uncompromised.
Embedded Security Modules are used across a spectrum of applications, catering to industries such as IoT, automotive, telecommunications, and consumer electronics. In the IoT realm, these modules protect smart devices from vulnerabilities and ensure secure data transmission between interconnected gadgets. In the automotive sector, ESMs safeguard vehicular communication systems and onboard diagnostics from hacking attempts. Similarly, telecommunications networks utilize these modules to establish secure channels and prevent espionage, maintaining the privacy of sensitive communications.
The products found within this category include a range of security-enhancing solutions such as secure boot processors, cryptographic accelerators, hardware random number generators, and secure element IPs. These products are designed to address specific security needs, offering flexibility and scalability to developers and manufacturers. For instance, secure boot processors ensure that only authenticated software runs on a device, while cryptographic accelerators speed up data encryption and decryption processes, vital for real-time secure communications.
Moreover, as digital threats evolve, Embedded Security Modules semiconductor IPs continue to advance, incorporating cutting-edge technologies like quantum encryption readiness and machine learning-led anomaly detection. This ongoing innovation not only fortifies existing systems but also prepares them for future challenges, making Embedded Security Modules a cornerstone of secure electronic design for years to come. Whether you are developing chips for personal gadgets or intricate industrial systems, integrating these security IPs ensures robust protection and compliance with stringent security standards, enhancing consumer trust and product reliability.
The aiWare NPU (Neural Processing Unit) by aiMotive is a high-performance hardware solution tailored specifically for automotive AI applications. It is engineered to accelerate inference tasks for autonomous driving systems, ensuring excellent performance across a variety of neural network workloads. aiWare delivers significant flexibility and efficiency, capable of scaling from basic Level 2 applications to complex multi-sensor Level 3+ systems. Achieving up to 98% efficiency, aiWare's design focuses on minimizing power utilization while maximizing core performance. It supports a broad spectrum of neural network architectures, including convolutional neural networks, transformers, and recurrent networks, making it suitable for diverse AI tasks in the automotive sphere. The NPU's architecture allows for minimal external memory access, thanks to its highly efficient dataflow design that capitalizes on on-chip memory caching. With a robust toolkit known as aiWare Studio, engineers can efficiently optimize neural networks without in-depth knowledge of low-level programming, streamlining development and integration efforts. The aiWare hardware is also compatible with V2X communication and advanced driver assistance systems, adapting to various operational needs with great dexterity. Its comprehensive support for automotive safety standards further cements its reputation as a reliable choice for integrating artificial intelligence into next-generation vehicles.
The AHB-Lite APB4 Bridge serves as a crucial interconnect that facilitates communication between the AMBA 3 AHB-Lite and AMBA APB bus protocols. As a parameterized soft IP, it offers flexibility and adaptability in managing system interconnections, bridging the gap between high-speed and low-speed peripherals with efficiency. The bridge's architecture is designed to maintain data integrity while transferring information across different protocol tiers. This bridge supports the implementation of a seamless transition for data exchanges, ensuring data packets are transmitted with minimal latency. It is ideal for systems that require stable connectivity across multiple peripheral interfaces, delivering a cohesive platform for system designers to enhance operational uniformity. By enabling efficient bus conversion, it supports broader system architectures, contributing to the overall efficiency of embedded designs. With its open-architecture design, the AHB-Lite APB4 Bridge caters to a wide range of applications, providing necessary adaptability to meet the unique demands of each project. Its robust design ensures that it can accommodate the complex architectures of modern embedded systems, enhancing both performance and reliability.
The AHB-Lite Multilayer Switch by Roa Logic is a sophisticated interconnect fabric that provides high performance with low latency capabilities. Designed for extensive connectivity, it supports an unlimited number of bus masters and slaves, making it ideal for large-scale system architectures. This switch ensures data is efficiently propagated through various paths, optimizing resource allocation and throughput in complex systems. With a focus on performance, the multilayer switch is crafted to manage data traffic within high-demand environments seamlessly. Its support for multiple layers allows it to efficiently handle concurrent data transactions, facilitating effective communication between different system components. The adaptive structure and controlled latency pathways enable it to fit a multitude of applications, including those requiring rapid data transfer and processing. The AHB-Lite Multilayer Switch is engineered to integrate seamlessly into modern system architectures, enhancing throughput without compromising on signal integrity. Its robust design and flexible configuration options make it indispensable within systems necessitating dynamic connectivity solutions.
CrossBar's ReRAM Memory brings a revolutionary shift in the non-volatile memory sector, designed with a straightforward yet efficient three-layer structure. Comprising a top electrode, a switching medium, and a bottom electrode, ReRAM holds vast potential as a multiple-time programmable memory solution. Leveraging the resistive switching mechanism, the technology excels in meter-scale data storage applications, integrating seamlessly into AI-driven, IoT, and secure computing realities. The patented ReRAM technology is distinguished by its ability to perform at peak efficiency with notable read and write speeds, making it a suitable candidate for future-facing chip architectures that require swift, wide-ranging memory capabilities. Unprecedented in its energy-saving capabilities, CrossBar's ReRAM slashes energy consumption by up to 5 times compared to eFlash and offers substantial improvements over NAND and SPI Flash memories. Coupled with exceptional read latencies of around 20 nanoseconds and write times of approximately 12 microseconds, the memory technology outperforms existing solutions, enhancing system responsiveness and user experiences. Its high-density memory configurations provide terabyte-scale storage with minimal physical footprint, ensuring effective integration into cutting-edge devices and systems. Moreover, ReRAM's design permits its use within traditional CMOS manufacturing processes, enabling scalable, stackable arrays. This adaptability ensures that suppliers can integrate these memory solutions at various stages of semiconductor production, from standalone memory chips to embedded roles within complex system-on-chip designs. The inherent simplicity, combined with remarkable performance characteristics, positions ReRAM Memory as a key player in the advancement of secure, high-density computing.
CrossBar's ReRAM IP Cores present a sophisticated solution for enhancing embedded NVM within Microcontroller Units (MCUs) and System-on-Chip (SoC) architectures. Designed to work with advanced semiconductors and ASIC (Application-Specific Integrated Circuit) designs, these cores offer efficient integration, performance enhancement, and reduced energy consumption. The technology seeks to equip contemporary and next-generation chip designs with high-speed, non-volatile memory, enabling faster computation and data handling. Targeting the unique needs of IoT, mobile computing, and consumer electronics, the ReRAM IP Cores deliver scalable memory solutions that exceed traditional flash memory limits. These cores are built to be stackable and compatible with existing process nodes, highlighting their versatility. Furthermore, the integration of ReRAM technology ensures improved energy efficiency, with the added benefit of low latency data access—a critical factor for real-time applications and processing. These IP cores provide a seamless route to incorporating high-performance ReRAM into chips without major redesigns or adjustments. As the demand for seamless, secure data processing grows, this technology enables manufacturers and designers to aptly meet the challenges presented by ever-evolving digital landscapes. By minimizing energy usage while maximizing performance capabilities, these IP cores hold potential for transformative applications in high-speed, secure data processing environments.
Polar ID from Metalenz offers a cutting-edge face unlock solution, using advanced meta-optic technology to provide secure, high-resolution facial recognition capabilities. It captures the unique "polarization signature" of a human face, making it resistant to both 2D photos and sophisticated 3D masks. Polar ID operates efficiently in a variety of lighting conditions, from bright daylight to dark environments, ensuring its utility extends across all smartphone models without sacrificing security or user experience. This technology replaces complex structured light modules, incorporating a single near-infrared polarization camera and active illumination source. It significantly reduces costs and footprint, supporting a broad adoption across hundreds of millions of mobile devices. With its low price point and high performance, Polar ID elevates smartphone security, offering robust protection for digital transactions and identity verification. By enabling this on an embedded platform with compatibility for Qualcomm's Snapdragon processors, Metalenz ensures widespread applicability. The key advantage of Polar ID is its affordability and ease of integration, as it eliminates the need for larger, more intrusive notches in phone designs. Its sophisticated polarization sensing means secure authentication is possible even if the user wears sunglasses or masks. Polar ID sets a new benchmark in smartphone security by delivering convenience and enhanced protection, marking it as the first polarization sensor available for smartphones.
Secure OTP by PUFsecurity offers a tamperproof data storage solution designed for the next generation of secure memory needs. It is an enhanced anti-fuse OTP memory that provides secure storage for key data across various forms, ensuring that data in transit, use, or rest remains protected. This technology integrates physical macros, a digital RTL controller, and a resilient anti-tamper shell to guard against hardware attacks. As IoT devices become increasingly susceptible to early-stage attacks, Secure OTP presents a reliable means to safely store sensitive data such as keys and boot code. By transitioning to this tamperproof storage format, devices can effectively mitigate vulnerabilities inherent in legacy storage systems, fortifying data security at the hardware level.
Securyzr iSSP is an integrated Security Services Platform designed by Secure-IC to offer comprehensive lifecycle management of device security. It provides zero-touch security lifecycle services that encompass provisioning, firmware updates, security monitoring, and device identity management. The platform employs a cloud-based architecture, enabling real-time updates and management of security protocols across a fleet of devices. Securyzr iSSP supports Post-Quantum Cryptography standards, ensuring readiness for future cryptographic challenges. This platform integrates seamlessly into diverse system environments, facilitating the protection of sensitive data through robust secure boot processes and key isolation techniques. It structures security around a core Root-of-Trust component named Securyzr iSE neo, which offers anti-tampering protection and dual computation for enhanced security. The platform aligns with an organization's security goals by providing customizable protective measures that are scalable to various applications. Securyzr iSSP is designed to maintain high security levels without compromising system performance or efficiency. By leveraging the latest advancements in cryptography and security protocols, it ensures the resiliency of systems against both physical and remote threats. This platform aids organizations in navigating the increasingly complex landscape of digital security challenges, providing a robust foundation for their cybersecurity strategies.
Up to 1M KeyEnc/sec with improved power efficiency PQPerform-Lattice is a powerful hardware-based product designed for high throughput, high-performance, and high speed. It adds post-quantum cryptography for applications that typically handle a large number of transactions, such as high-capacity network hardware applications and secure key management HSMs. Optimizable for secure boot, as well as other use-cases, PQPerform-Lattice supports FIPS 204 ML-DSA for quantum-secure digital signature verification, as well as FIPS 203 ML-KEM for quantum key exchange. PQPerform-Lattice supports AXI4, PCIe, and is deployable in multiple instances, making it a powerful solution for existing systems and infrastructure requirements.
FIPS 140-3 CAVP-compliant, compact PQC hardware acceleration for subsystems PQPlatform-CoPro combines hash-based and lattice-based post-quantum cryptography that can be added to an existing security subsystem. It can be optimized for minimum area, maintaining high-performance, and is designed to be run by an existing CPU using PQShield-supplied firmware, meaning it involves low integration effort and flexible configurations to support a wide variety of use cases, including quantum-safe secure boot. Solutions are available for hardware acceleration of SHA-3, SHAKE, ML-KEM, ML-DSA, alongside traditional cryptography. In addition, PQPlatform-CoPro can be configured with side-channel protection. PQPlatform-CoPro is covered by multiple PQShield implementation patents.
The ultra-low-power human body detector from Microdul is engineered to provide efficient, static detection capabilities essential for wearable technology. This detector helps significantly reduce energy consumption in devices when not actively in use. Its advanced design allows it to recognize the presence or absence of a human, making it ideal for applications requiring power-saving features, such as smart devices and IoT equipment. The precise nature of its operation ensures long battery life, thereby enhancing the user experience in battery-dependent gadgets. Moreover, its application in static detection means it can operate seamlessly without requiring constant recalibration or complex interfacing. Its implementation is particularly valuable in the wearables market where minimizing power draw while maintaining functionality is a critical competitive factor. With its ability to integrate smoothly into existing systems, this detector forms an indispensable part of power-efficient device design strategies focused on long-term effectiveness in changing environments. Its versatility extends to various industries, ensuring compatibility with diverse technological ecosystems while emphasizing seamless operation and reliability. As a result, it paves the way for new possibilities in the design of cutting-edge consumer electronics.
FIPS 140-3 CAVP-compliant, compact lattice-based hardware PQC engine PQPlatform-Lattice is a compact FIPS 140-3 CAVP-compliant, PQC engine that adds post-quantum support for hardware components and embedded devices, using lattice-based cryptographic algorithms such as ML-KEM (FIPS 203) for post-quantum key exchange, and ML-DSA (FIPS 204) – post-quantum digital signature verification. It provides secure acceleration of lattice-based PQC alongside support for traditional cryptography. Its use cases include strong user authentication, protecting hardware keys, and small-footprint, configurable side-channel protection. PQPlatform-Lattice is designed for minimal area as well as maximum compatibility and can be deployed with optional firmware-backed side-channel countermeasures. It is covered by multiple PQShield implementation patents.
The eSi-Crypto suite by EnSilica is a comprehensive collection of cryptographic IP cores designed for both ASIC and FPGA architectures, aiming for minimal resource consumption while ensuring high throughput. A key component within this suite is the True Random Number Generator (TRNG), which adheres to NIST 800-22 standards and is offered as a hard macro in target technologies. Its configurable options are tailored to balance resource efficiency with throughput, making it essential for robust encryption solutions. These IP cores are available as stand-alone modules or integrated with AMBA APB/AHB or AXI bus interfaces.\n\nThe suite supports a variety of cryptographic algorithms such as CRYSTALS Kyber, CRYSTALS Dilithium, elliptic curve cryptography (ECC/ECDSA), RSA, AES, SHA1/SHA2/SHA3, ChaCha20, Poly1305, and TDES/DES. These diverse implementations can be tailored for specific use cases, including high-throughput core configurations ideal for applications like V2X communications. Additionally, the suite's ECC/ECDSA capabilities provide secured digital signature mechanisms, critical for applications requiring stringent data integrity and authenticity.\n\nEnSilica's dedication to cryptographic excellence is further evidenced in their sophisticated handling of secure web-server implementations. By leveraging their ultra-low-power accelerators, particularly for algorithms like ChaCha20 and Poly1305, eSi-Crypto reduces computational overhead while optimizing security performance. This makes the suite a preferred choice for customers seeking efficient and reliable cryptographic solutions across varied technology platforms.
Trilinear Technologies' HDCP Encryption-Decryption Engine is a sophisticated solution designed to safeguard digital content as it traverses various transmission channels. This engine is compliant with the HDCP standards 1.4 and 2.3, offering robust protection mechanisms to ensure that digital media investments are secure from unauthorized access and piracy. The engine’s hardware acceleration capabilities represent a crucial advantage, significantly reducing the load on the system processor while maintaining real-time encryption and decryption functions. This not only enhances performance but also extends the operational life of the hardware involved, making it suitable for high-demand media applications across sectors such as broadcast, entertainment, and corporate environments. Trilinear’s HDCP Encryption-Decryption Engine ensures compatibility with a wide array of consumer and professional-grade video equipment, providing seamless protection without interference in media quality or transmission speed. Its flexible integration options allow it to be smoothly incorporated into existing infrastructures, whether in standalone media devices or complex SoC architectures. Supported by comprehensive software resources, the HDCP Encryption-Decryption Engine provides an all-encompassing solution that includes necessary software stacks for managing device authentication and link maintenance. Its ability to safeguard high-definition content effectively makes it an invaluable asset for entities focused on secure content delivery and rights management.
Designed for high-resolution brain recordings, the Neuropixels Probe is an advanced tool for neuroscience research, offering direct insight into brain activity with unprecedented precision. It enables large-scale data collection across numerous brain regions simultaneously, which is vital for mapping and understanding complex neural circuits. This probe features an array of dense electrodes, making it possible to record from hundreds of neurons at once. Its compact, lightweight design allows for chronic implantation, facilitating long-term brain studies without compromising subject mobility. With its exceptional signal processing capabilities, the probe supports detailed neural data analysis, proving indispensable for neuroscientists aiming to explore new frontiers in brain functionality and disorders. The probe’s integration with CMOS technology ensures high-density data capture with reduced interference and improved accuracy.
The NS Class is Nuclei's crucial offering for applications prioritizing security and fintech solutions. This RISC-V CPU IP securely manages IoT environments with its highly customizable and secure architecture. Equipped to support advanced security protocols and functional safety features, the NS Class is particularly suited for payment systems and other fintech applications, ensuring robust protection and reliable operations. Its design follows the RISC-V standards and is accompanied by customizable configuration options tailored to meet specific security requirements.
The FPGA Lock Core is an innovative FPGA solution designed to secure FPGAs and hardware against unauthorized access and counterfeiting, leveraging a Microchip ATSHA204A crypto authentication IC. It reads a unique ID, generates a 256-bit challenge, and uses secure hashing to verify the hardware's authenticity, ensuring hardware integrity in sensitive applications like military and medical fields. This solution allows hardware protection against IP theft by enforcing authentication and disables FPGA functionality if unauthorized access is detected. The core utilizes minimal logic resources and one FPGA pin, communicating through a bidirectional open drain link. The clarity of this system is enhanced by providing the core in VHDL, allowing users to thoroughly understand its functionality, supported by example designs on Cyclone10 and Artix 7 boards, catering to both Intel and Xilinx FPGA platforms. Complementing this security measure is the Key Writer Core, which allows programming of custom secret keys into the ATSHA204A in situ on assembled boards, ensuring a seamless integration with the FPGA Lock system. Available for various FPGA platforms, the Efinix version, distributed with TRS Star, expands its applicability, with webinars and user guides offering in-depth implementation insights.
The Individual IP Core Modules by ResQuant are comprehensive components engineered to support diverse post-quantum cryptographic standards, including Dilithium, Kyber, XMSS, SPHINCS+, AES, and the SHA-2 family. These modules offer organizations the flexibility to select specific cryptographic functionalities tailored to their security needs, without the necessity of entire systems or hardware changes. Each module is designed to integrate easily into existing infrastructure, ensuring minimal disruption while enhancing security measures against potential future quantum threats. This approach allows industries to gradually implement PQC standards, ensuring a seamless transition to quantum-resistant cryptographic measures. Tailored for flexibility, the ResQuant Individual IP Core Modules can be used across a wide array of applications, from IoT devices to complex military and IT systems. By offering component-level integration, these modules empower companies to future-proof their offerings incrementally while maintaining robust security practices in their operations.
Suite-Q SW is a versatile cryptographic software library designed to offer flexibility in code size, performance, and memory usage, making it an essential tool for developers working on resource-limited devices. Engineered for high adaptability, this software package provides a robust framework for implementing secure cryptographic operations across diverse platforms, including 8-bit to 64-bit processors. The library is meticulously crafted to support various configuration options that balance speed with memory efficiency, ensuring it meets custom specifications while preserving system integrity. Portable C code and high-speed, hand-optimized assembly variants are available to provide the ideal blend of compatibility and performance required in modern applications. Key features of Suite-Q SW include seamless integration as plug-in modules, support for a wide range of hardware offloads, and extensive compatibility with general-purpose and embedded CPUs. Validated through rigorous testing and performance measurements, it provides a reliable basis for secure software development, ensuring rapid deployment with minimized risk. As such, Suite-Q SW remains an indispensable part of PQSecure's comprehensive cryptographic offerings, perfect for adapting to the ever-changing landscape of digital security.
Suite-Q HW is a robust system-on-chip (SoC) solution that envelops all the necessary cryptography required for secure protocols within compact and efficient hardware. Targeted at both high-end servers and low-end embedded systems, this solution emphasizes the dual benefits of scalability and adaptability. Suite-Q HW efficiently offloads demanding symmetric and asymmetric cryptographic processes by leveraging specialized accelerators, offering enhanced execution speeds that cater to different application requirements. A key component of its utility lies in its support for a wide array of cryptographic operations. This includes classical public key methods, such as ECDSA and ECDH, alongside emerging post-quantum techniques within isogeny and lattice frameworks. The hardware is further augmented by secure hash algorithms and diverse AES encryption modes, delivering comprehensive protection across a variable security landscape. Incorporating optional Differential Power Analysis (DPA) countermeasures and validated security standards, Suite-Q HW ensures security for sensitive data against contemporary and emerging threats. It facilitates integration with existing development flows across SoCs and FPGAs, optimizing power and silicon footprint according to specific needs. Furthermore, the hardware package provides comprehensive resources for integration, from testbench data to simulation scripts, enhancing its adaptability and effectiveness in today's digital security paradigm.
Highly-optimized PQC implementations, capable of running PQC in < 15kb RAM PQCryptoLib-Emebedded is a versatile, CAVP-compliant version of PQCryptoLib, PQShield’s CMVP-certified library of post-quantum cryptographic algorithms. With its design focused on ultra-small area efficiency, PQCryptoLib-Embedded has been specifically designed for embedded systems, microcontrollers and memory-constrained devices. It could be the first step towards a hardware solution for providing PQC integration to devices already in the field.
NeoPUF is revolutionizing hardware security by providing up to 100 times faster random number generation. This advanced security technology plays a critical role in safeguarding semiconductor devices against emerging threats. It incorporates a hardware-based random number generator which powers the development of the next generation of secure chips, ensuring robust protection from unauthorized access. Positioned as a critical component in the development of secure semiconductors, NeoPUF integrates seamlessly into existing systems, offering a quantum-resilient solution. This capability is vital in defense against potential quantum-era threats, providing security that remains effective even as technology landscapes shift. NeoPUF supports operations across diverse applications, particularly in sensitive environments where data integrity is paramount. As part of PUFsecurity's comprehensive lineup, NeoPUF not only enhances secure storage options but also facilitates reliable identification and anti-cloning features. It is a key enabler of trusted computing across numerous industries, underlining its importance in the modern era where security is indispensable.
The patented QDID PUF by Crypto Quantique utilizes quantum tunneling current variations to produce a unique identity in standard CMOS processes. This solution leverages oxide thickness variations and trap distributions in the gate oxide to create an unpredictable and unclonable physically unclonable function (PUF). As a hardware root-of-trust, it simplifies secure provisioning and emits high-entropy seeds resistant to side-channel attacks, supporting up to 256-bit security strength. The QDID PUF's robustness is confirmed through extensive testing, including adherence to NIST standards, making it an ideal choice for secure device identity and post-quantum cryptographic applications.
Secure Protocol Engines by Secure-IC focus on enhancing security and network processing efficiency for System-on-Chip (SoC) designs. These high-performance IP blocks are engineered to handle intensive security tasks, offloading critical processes from the main CPU to improve overall system efficiency. Designed for seamless integration, these modules cater to various applications requiring stringent security standards. By leveraging cryptographic acceleration, Secure Protocol Engines facilitate rapid processing of secure communications, allowing SoCs to maintain fast response times even under high-demand conditions. The engines provide robust support for a broad range of security protocols and cryptographic functions, ensuring data integrity and confidentiality across communication channels. This ensures that devices remain secure from unauthorized access and data breaches, particularly in environments prone to cyber threats. Secure Protocol Engines are integral to designing resilient systems that need to process large volumes of secure transactions, such as in financial systems or highly regulated industrial applications. Their architecture allows for scalability and adaptability, making them suitable for both existing systems and new developments in the security technology domain.
Fully autonomous, FIPS 140-3 CAVP compliant PQC subsystem PQPlatform-SubSys is a cryptographic subsystem, designed to provide offloaded cryptographic services with minimal integration effort and full autonomy from an existing security subsystem, as well as configurable side-channel protection. These services include post-quantum signature generation, verification, and secure key establishment. It’s built with optimal performance in mind, as well as crypto agility with its provision of traditional, PQ/T hybrid and fully post-quantum algorithms. PQPlatform-SubSys uses its built-in RISC-V CPU independently from the surrounding system, allowing cryptographic services to be offloaded efficiently from the system processor.
VeriSyno Microelectronics offers Digital Systems and Security Solutions designed to enhance the robustness and efficiency of modern digital applications. This comprehensive suite includes IPs for PSRAM interfaces, network protocols like vMAC, and security mechanisms, addressing the critical needs for secure and efficient digital communications. The digital solutions are engineered to meet stringent security protocols, ensuring data integrity and protection in various applications. VeriSyno's expertise in digital system design enables the development of reliable solutions that integrate seamlessly into existing infrastructures, enhancing both system performance and security. These solutions are suitable for a broad spectrum of digital applications, including consumer electronics, automotive, and industrial systems, where efficient data handling and security are paramount. With ongoing innovation, VeriSyno maintains its competitive edge by adapting to emerging industry requirements and introducing forward-thinking digital solutions.
The SHA-3 Crypto Engine is a hardware accelerator designed for cryptographic hashing, offering high throughput and area efficiency. It adheres to the NIST FIPS 202 standard, supporting all variants of the SHA-3 family, including SHA-3-224, SHA-3-256, SHA-3-384, and SHA-3-512, along with extendable output functions SHAKE-128 and SHAKE-256. Designed to resist time-based side-channel attacks, this IP core is integrated as a fully synchronous design supporting AMBA AXI4-Stream interfaces, making it versatile for various secure applications. Applications for the SHA-3 Crypto Engine span from secure message authentication to encryption protocols within IPsec and TLS/SSL engines, secure boot processes, and decentralized blockchain technologies. It is particularly suitable for e-commerce platforms and financial transaction processing, where data integrity and authenticity are paramount. Its ease of integration and robust performance ensure it is a preferred choice for next-generation security solutions. Offering resource-optimized performance, the SHA-3 engine is available with a range of deliverables, including Verilog RTL, testbenches, and comprehensive documentation. Its resource utilization across different FPGA and ASIC platforms demonstrates compatibility and efficiency, ensuring developers can implement secure hashing functions seamlessly within their devices.
Designed to scale effectively with the growing needs for high-volume data storage, CrossBar's ReRAM IP Cores for High-Density Data Storage offer clients the ability to manage extensive datasets with ease. The cores excel in providing high-speed data access and retrieval capabilities, making them an ideal choice for data centers, AI infrastructure, and complex analytics platforms. These cores support dense data storage configurations within devices, far surpassing the performance specifications of traditional memory options. CrossBar's ReRAM cores offer significant energy savings in storage operations, enabling data centers to drastically reduce power consumption while increasing throughput and efficiency. This green approach to data storage not only enhances computational performance but also aligns with global sustainability efforts to lower energy expenditure. With high-density capabilities, the ReRAM cores play a critical role in optimizing large-scale data handling and facilitate emerging trends like real-time analytics and advanced machine learning algorithms. Integrated into existing infrastructures, these ReRAM cores transcend traditional memory solutions. The technology's flexibility allows for customization, accommodating varied client needs and extending beyond standard operational limitations. Whether deployed in cloud services, enterprise data warehousing, or sophisticated AI training models, CrossBar's ReRAM cores ensure robust performance, reliability, and scalability in handling complex storage challenges.
Cologne Chip’s C3-CODEC-G712-4 is an advanced audio codec IP core that forms part of the renowned DIGICC-based ASIC IP lineup. This codec is tailored for efficient audio signal processing and supports a variety of telecommunication applications. What distinguishes the C3-CODEC-G712-4 is its ability to deliver high-fidelity audio through a fully digital approach, which streamlines the integration into various digital platforms, eliminating the complexity associated with analog audio signal management. Designed for robust performance, this codec ensures minimal latency and high efficiency in audio compression and decompression, making it an ideal choice for real-time communication systems. Its compact design and digital architecture allow for seamless compatibility with modern telecommunication infrastructure, providing users with excellent signal clarity without a significant resource footprint. Furthermore, Cologne Chip supports the C3-CODEC-G712-4 with extensive documentation and integration tools, easing its adoption into new and existing systems. This codec plays a critical role in enhancing the audio quality of communication systems while maintaining cost-effectiveness, thanks to the reduced need for external analog components and converters traditionally required in audio processing.
The CANsec Controller Core is engineered to provide enhanced security features for automotive CAN networks. Traditional CAN networks are not inherently secure, posing challenges in protecting against unauthorized access and data tampering. This controller core integrates security protocols directly into the CAN framework, offering an encryption-enabled solution tailored for modern automotive needs. This controller core implements standardized security measures, ensuring confidentiality, integrity, and authenticity of CAN messages. By incorporating advanced cryptographic algorithms, the CANsec Controller Core meets stringent security requirements without compromising the performance that automotive applications demand. Its design focuses on minimizing resource consumption while providing robust security enhancements. Ideal for vehicles requiring secure communication between various electronic control units (ECUs), the core upholds the automotive industry’s increasing emphasis on cybersecurity. The CANsec Controller Core is versatile in its implementation, suitable for both new vehicle architectures and as an upgrade to existing systems, making it a vital component of future-proof automotive design.
The High-Performance Computing (HPC) Platform from SEMIFIVE is crafted to meet the demands of computationally intensive tasks and data-centric applications. This platform is tailored for environments that require high-speed computations and advanced data handling capabilities, featuring leading-edge processor technologies and interconnect architectures. Capable of supporting heavy data processing and complex simulations, the platform integrates the latest in processor designs with high-speed memory interfaces and robust I/O capabilities. The emphasis on optimizing throughput, latency, and efficiency makes it well-suited for use in data centers, research labs, and industrial applications needing massive data analytics power. Integrating high-bandwidth and low-latency networking capabilities, the platform ensures seamless data flow and processing. It provides scalable solutions that adapt to changing workloads, making it ideal for cloud services, real-time analytics, and AI-intensive tasks, offering robust performance characteristics that are crucial for next-gen computing environments.
Secure-IC's Post-Quantum Cryptography IP offers robust, future-ready security for digital communications, addressing the challenges of quantum computing on traditional encryption methods. This IP is crucial for systems that require long-term confidentiality and authenticity of data, ensuring they remain secure against threats posed by advancements in quantum computing. Designed to integrate seamlessly into existing hardware and software infrastructures, the Post-Quantum Cryptography IP is adaptable and scalable, providing flexibility in implementation. It supports a variety of cryptographic algorithms specifically chosen for their resistance to quantum attacks, ensuring they meet the highest security standards. By adopting this technology, systems can safeguard against potential future vulnerabilities that quantum processors might exploit. This IP is an essential component for industries looking to fortify their security measures, particularly in sensitive sectors such as defense, finance, and critical infrastructure. It provides a forward-thinking approach to cybersecurity, aligning with global trends and regulatory requirements for enhanced cryptographic solutions. By securing today’s systems against tomorrow’s threats, this IP is a strategic investment in sustained security resilience.
Tailored for applications requiring secure non-volatile memory, CrossBar's ReRAM as FTP/OTP Memory offers a refined solution for few-time programmable (FTP) and one-time programmable (OTP) needs. Leveraging the intrinsic properties of ReRAM technology, these applications benefit from reduced write requirements and minimized area without compromising security or performance. This ReRAM variant integrates effectively within standard CMOS processes, providing adaptability whether used independently or embedded within more complex systems. Its non-volatility and high density make it a preferred choice for secure applications where cost-efficient data integrity is essential. The technology supports diverse applications across numerous sectors including automotive, medical, and industrial systems, where quick response times and reliability are critical. The FTP/OTP ReRAM enables provisioning for physical unclonable functions (PUF), further enhancing its security capabilities. Such an implementation provides resistance to invasive attacks and maintains data integrity even under adverse conditions. These features position ReRAM as a powerful tool for managing sensitive data operations and broad pursuits in modern digital infrastructures.
The Customizable Cryptography Accelerator offered by ResQuant is designed to meet varied client needs with an extensive array of configurable options. It integrates seamlessly with all NIST PQC standards like Dilithium, Kyber, XMSS, and SPHINCS+, and is extendible with additional algorithms, including customer-specific implementations. The accelerator is built to be DPA, timing, and SCA resistant, and is AXI 4 ready, ensuring robust protection in a variety of applications. This innovation allows for customizable tuning in performance and size, addressing the specific security requirements of customers from various industries. The accelerator demonstrates ResQuant's commitment to flexibility and adaptability, enabling clients to implement cutting-edge encryption with ease. With ongoing enhancements to extend its capabilities, the accelerator stands as a critical component in defenses against future computational threats posed by quantum technologies. In addition to its technical capabilities, the ResQuant Customizable Cryptography Accelerator is engineered for efficient power use and minimized physical footprint, making it suitable for integration into a wide range of hardware setups. This solution underscores ResQuant's dedication to delivering high-security standards and unmatched versatility in cryptographic processing solutions.
Engineered for energy-sensitive applications, Microdul’s capacitive proximity switch combines precision with ultra-low-power consumption, making it ideal for modern technological needs. This switch is designed to detect touch reliably without direct physical contact, thereby facilitating advanced user interfaces, particularly in devices where minimizing energy usage is critical. The switch’s lightweight design and responsive detection capability allow it to support numerous applications such as touchpads and sliders commonly used in consumer electronics. Its capacitive nature ensures swift response times, making it suitable for dynamic environments where instant feedback is necessary, such as in user interface control panels. Applications extend to smart technology fields, where energy savings can be maximized. The capacitive proximity switch continues to function effectively across various climates and conditions, promising versatility and adaptability. By enhancing system efficiency through minimal power demands, it impressively complements design strategies that focus on sustainability and long-term operational economy.
PhantomBlu is a sophisticated mmWave communication solution specifically designed for the defense sector, empowering military operations with robust, high-performance connectivity. Leveraging advanced mmWave technology, it supports tactical connections between land, sea, and air platforms, enabling seamless IP networking over a secure, anti-jam resistant mesh network. PhantomBlu’s design is optimized for rapid deployment and versatile use across various challenging military and defense environments. The PhantomBlu system offers unprecedented connectivity and integration capabilities, supporting high-bandwidth, low-latency communications essential for defense operations. It features LPI (Low Probability of Interception) and LPD (Low Probability of Detection), ensuring stealth and operational security. Its adaptive networking solutions significantly enhance situational awareness and interoperability amongst varied defense assets, assuring seamless transfer of C4ISR data. Whether deployed across large terrains or in mobile units, PhantomBlu's resilience and scalability ensure that defense teams operate with confidence. Its advanced capabilities are critical in mitigating risks and enhancing strategic emission, making it an invaluable asset for modern military communications needs.
PQSecure's Cryptographic Core serves as a comprehensive solution for implementing standardized cryptographic algorithms within system-on-chip (SoC) designs. This product is tailored for diverse applications, ranging from high-end servers to low-end embedded systems, ensuring broad compatibility. It effectively offloads both symmetric and asymmetric cryptographic operations, boosting execution efficiency. The core includes hardware accelerators capable of performing various cryptographic functions, such as true random number generation and classical public key cryptographic algorithms like ECDSA and ECDH. Incorporating next-generation post-quantum cryptographic methods, this core tackles the imminent threats posed by quantum computing. By supporting isogeny-based, lattice-based, and code-based cryptographies, it prepares systems for the quantum evolution. Furthermore, this Cryptographic Core supports secure hashing algorithms and a variety of advanced encryption standards, ensuring robust protection across different security levels recommended by standardization bodies. As an embodiment of both agility and security, it integrates seamlessly into various SoC and FPGA architectures, providing substantial power reductions compared to traditional software implementations. Designed with future-proofing in mind, PQSecure's Cryptographic Core features optional side-channel protection mechanisms validated by standard techniques, delivering DPA countermeasures without significant overhead. It boasts a comprehensive suite of verification tools, including test benches and simulation scripts, making integration into existing systems both easy and efficient. With customizable performance profiles, the Cryptographic Core is engineered to meet the demanding security requirements of tomorrow's digital environments.
Comcores' MACsec solution addresses the needs for secure communication on Ethernet links by implementing the IEEE 802.1AE standard for MAC Security. It provides comprehensive protection against eavesdropping and manipulation, making it suitable for applications demanding high security over public and private networks. Built to support various data rates, the MACsec IP core integrates robust cryptographic suites like AES-GCM to encrypt and authenticate network traffic. Its deployment ensures data confidentiality and integrity, fostering a secure environment for transmitting sensitive information such as in military communication systems and data centers.
Chuangfeixin Technologies' OTP (One-Time Programmable) solutions provide a unique approach to secure data storage. Once programmed, the data within these OTP devices is immutable, providing a robust layer of security ideal for protecting intellectual property and sensitive information within integrated circuits or logic gates. These solutions are particularly advantageous in embedded applications, where they can safeguard firmware and configuration data against unauthorized access or alteration. The company offers versatile OTP products compatible with various CMOS processes, ensuring easy integration without additional processing steps, thus reducing development costs. The long data retention of over 100 years under extreme conditions further underscores the reliability of these OTP modules in demanding applications.
The Security Protocol Accelerator from PQSecure is a pivotal component in enhancing the performance of cryptographic operations within embedded systems and processors. This accelerator facilitates the efficient execution of security protocols, such as post-quantum cryptographic algorithms, providing hardware-accelerated computation to offload intensive tasks from the main CPU. PQSecure's accelerator design focuses on optimizing the speed and efficiency of complex cryptographic tasks, including key exchange operations, digital signatures, and hashing. It is engineered to support a broad spectrum of cryptographic standards while maintaining configurability for various security and performance levels. This product stands out due to its ability to integrate seamlessly into various processor architectures and its compatibility with existing SoC and FPGA platforms. Key features of the Security Protocol Accelerator include customizable performance settings and support for both classical and post-quantum cryptographic operations. It provides significant improvements in power efficiency and computational speed, ensuring systems are prepared for future quantum challenges. With available side-channel attack countermeasures, this accelerator not only secures data but also mitigates potential vulnerabilities common in cryptographic implementations.
CoMira Solutions offers a Media Access Control Security (MACSec) solution adhering to IEEE standards aimed at safeguarding communication within 802.1 LAN environments. MACSec ensures data confidentiality and integrity, preventing unauthorized access and disruptions. It employs advanced encryption standards and supports flexible traffic management through various port configurations. The MACSec IP's time-division multiplexed architecture aligns seamlessly with CoMira's UMAC, ensuring synchronous operation despite differing link speeds. This implementation includes FIPS-compliant encryption methods such as GCM-AES-128 and GCM-AES-256, supporting robust security needs. Furthermore, CoMira's MACSec supports multiple secure channels and security associations per port, adding layers of protection to client systems. The configurability of Secure Channels and the ability to strip security tags enhances its adaptability in varied networking scenarios, reflecting CoMira's commitment to delivering tailor-fit security solutions.
The Cramium Personal Hardware Security Module (PHSM) by CrossBar is an integrated security solution that enhances digital asset security through its advanced ReRAM technology. Built with the capability for Multi-Party Computation (MPC), the Cramium PHSM provides robust key protection by eliminating the need for key reconstruction, thus reducing vulnerability to attacks. Utilizing FIDO2 authentication, the module is designed with an offline-by-default architecture, ensuring high assurance levels in protecting sensitive data. This protection is particularly crucial for applications operating within decentralized systems where security is paramount. Combining innovative memory and cryptographic technology, the Cramium PHSM is crafted to meet varying compliance needs, making it ideal for industries such as finance, healthcare, and information technology. The module enhances tamper resistance for cryptographic operations, ensuring secure storage and operation of sensitive information within protected environments. One of its unique features is the ability to offer robust authentication without relying on external network connectivity, effectively insulating assets from unauthorized access. Cramium PHSM exemplifies CrossBar's commitment to developing secure solutions for complex challenges presented by modern computational demands. Its modular design enables easy customization and integration, catering to specific industry requirements and assuring enterprises of enhanced cryptographic functionalities. The module not only safeguards digital secrets but also introduces an improved fault-tolerant element that minimizes risk from potential breaches or exploits.
MIFARE Certification Technologies provide a comprehensive suite for certification related to mobile and IoT platforms. This technology is at the forefront of ensuring compliance and reliability in embedded systems used within public transportation and personal devices. It focuses on ensuring that devices meet rigorous global standards for communication and data transfer security. Utilizing robust protocols, these technologies facilitate seamless integration with existing infrastructures, promoting enhanced accessibility and user experience. The certification process involves extensive validation checks to ensure system integrity, sustainability, and efficient operation within diverse environments. By certifying embedded software, it supports manufacturers in achieving compliance with regulatory requirements, empowering them with a market advantage. This technology is essential for companies looking to maintain competitive status by ensuring their products meet necessary communication standards. It demonstrates a commitment to quality and security in data handling, solidifying a product's credibility and operational reliability. MIFARE Certification Technologies pave the way for future-ready solutions, blending technological prowess with market needs.
Specializing in ESD protections, Certus Semiconductor offers highly adaptive solutions that meet various operational demands. These circuits provide enduring defense against ESD threats, surpassing traditional HBM and CDM specifications. Capabilities include low capacitance solutions and customized protections tailored to endure voltages between -18V to +30V. These ESD circuits are integrated with specialized features like Rad-Hard technology, high-temperature resilience, and enhanced burst immunity, setting a standard for highly secure semiconductor solutions in harsh environments.
FortiCrypt offers a robust and secure cryptographic framework specifically designed to thwart side-channel and fault injection attacks. This suite of cryptographic IP includes advanced protection mechanisms that ensure both high security and performance across various platforms. The IP core is meticulously engineered to deliver ultra-low power consumption, making it ideal for battery-operated and IoT devices. The FortiCrypt product line is versatile, supporting a wide array of cryptographic algorithms, including both classical and post-quantum variations. It integrates seamlessly with existing systems, requiring minimal integration overhead, and is validated to withstand real-world attacks. Its high bandwidth capacity, achieved through multi-pipeline architecture, makes FortiCrypt suitable for high-performance applications, ensuring rapid data throughput without compromising security. Furthermore, FortiCrypt's compliance with the highest industry standards, such as FIPS 140-3 and SESIP, assures its usage in applications requiring stringent security measures. Whether used for secure communication, data protection, or hardware defense, FortiCrypt establishes a fortress against unauthorized access and data breaches, demonstrating unparalleled resilience and efficiency.
The Platform-Level Interrupt Controller (PLIC) by Roa Logic is a comprehensive solution for managing interrupt signals in sophisticated and large-scale computing environments. Compatible with RISC-V platforms, it is fully parameterised and offers an efficient means to handle and prioritize multiple interrupt sources. The PLIC's design emphasizes scalability and flexibility, allowing developers to adapt the module for a wide range of system requirements. The PLIC supports a configurable number of interrupt sources, each with customizable priority levels. This enables a tailored approach to the handling of critical interrupts, ensuring that high-priority tasks receive immediate attention. It serves as an essential building block for systems that demand precise and reliable interrupt management, making it indispensable in complex processor environments. With its easy integration into existing RISC-V platforms, the PLIC provides a seamless upgrade to traditional interrupt controllers. Its high level of adaptability ensures that it can be calibrated to complement specific system architectures, enhancing performance in varied operational scenarios.
NVM Defender is crafted to bolster the protection of non-volatile memory on integrated circuits against unauthorized access and data breaches. With a cutting-edge architecture, this product secures sensitive information stored within ICs, employing robust measures to counter invasive and non-invasive attack vectors. NVM Defender is pivotal in environments where data integrity and confidentiality are paramount, ensuring that sensitive data remains shielded from potential threats. The technology integrates seamlessly with various IC designs, providing a comprehensive security layer without affecting the performance of the primary device functions. It is engineered to withstand sophisticated threats, capturing and neutralizing attempts to access or alter stored data illicitly. Industries reliant on secure data transfer and storage leverage this product to maintain high levels of security across their hardware. Designed with adaptability in mind, NVM Defender can be implemented across different industries, offering scalable security solutions tailored to the specific demands of various fields such as automotive, aerospace, and consumer electronics.
The AES Crypto core from Dillon Engineering offers robust encryption capabilities tailored for secure communications and data protection. Designed to implement the Advanced Encryption Standard (AES), this core is perfect for safeguarding sensitive information across various digital platforms. Known for its reliability and security, the AES core ensures that encryption operations are performed with high efficiency and minimal latency. With a strong focus on protection, the AES Crypto core integrates advanced cryptographic algorithms that provide a secure environment suitable for financial transactions, secure data storage, and confidential communication. The core's architecture supports various key lengths and modes of operation, accommodating the diverse security needs of users. Committed to maintaining data integrity and confidentiality, this core balances performance with heightened security measures. Able to fit into a range of systems, it provides robust solutions that meet stringent industry standards, making it a preferred choice for applications that require uncompromised data protection.
FortiPKA-RISC-V is a powerful public key algorithm coprocessor designed to enhance cryptographic operations through streamlined modular multiplication techniques. This IP core offers robust protection against side-channel and fault injection attacks, ensuring high performance by eliminating Montgomery domain transformations. Engineered to maximize efficiency, FortiPKA-RISC-V supports a variety of cryptographic protocols, making it suitable for applications demanding high-speed data processing with minimal latency. Its architecture ensures seamless integration into systems requiring secure key exchanges and digital signature verifications, showcasing versatility across different computational platforms. Additionally, this coprocessor is built with a focus on reducing hardware footprint, making it ideal for space and power-conscious applications such as embedded systems and mobile devices. By aligning with industry-standard cryptographic requirements, FortiPKA-RISC-V provides an effective solution for environments requiring elevated security without compromising on computational speed or area efficiency.
The Keccak Hash Engine is known for its versatility in cryptographic operations, supporting a broad range of functions beyond traditional hashing. Notably, it serves as a foundational element for hash functions, authentication, encryption, and pseudo-random number generation. This IP core employs the innovative sponge construction technique and the Keccak-f permutation, renowned for its simplicity and adaptability. Keccak has been internationally standardized within several specifications, including NIST's FIPS 202 for SHA-3 and the 3GPP TS 35.231 for mobile telecommunications. This extensive scrutiny and third-party analysis ensure its suitability for highly secure applications. The Keccak Hash Engine excels in scenarios demanding configurable security levels or output lengths, integrated seamlessly into various systems. Built for integration ease and robust security, the Keccak IP core operates within a single clock domain and comes extensively verified. It provides a strong foundation for applications in security, data integrity, blockchain technologies, and secure data storage, extending the potential of cryptographic protections within embedded systems.
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