Intel Atom P5731

The Intel processor number is just one of several factors, along with processor brand, system configuration, and system-level benchmarks, that you should consider when choosing the right processor for your computing needs. Learn more about interpreting Intel processor numbers® or Intel processor numbers® for data centers.

Lithography refers to the semiconductor technology used to produce an integrated circuit and is expressed in nanometers (nm), which indicates the size of the features built on the semiconductor.

Recommended Customer Price (RCP) is an indicative price for Intel products only. Prices are based on Intel direct customer purchases, are typically based on purchase quantities of 1,000 units, and are subject to change without notice. Prices may vary for other types of packaging and number of shipments. When selling in bulk, the price is per individual unit. The RCP listing is not an official Intel price quote. RCP values may vary depending on tariffs.

Cores are a hardware term that describes the number of independent central processing units in a single computing component (die or chip).

Where applicable, Intel technology® Hyper-Threading is only available for high-performance cores.

Processor Base Frequency describes the rate at which the processor’s transistors open and close. The processor base frequency is the operating point where TDP is defined. Frequency is typically measured in gigahertz (GHz), or billion cycles per second. For more details regarding the dynamic power and frequency operating range, refer to <a

The processor cache is an area of fast memory located on the processor. Intel® Smart Cache refers to an architecture that allows all cores to dynamically share access to the last level cache.

Intel Channels® Ultra Path Interconnect (UPI) is a high-speed internetworking bus «point-to-point» between processors, providing increased throughput and performance compared to Intel® QPI.

QPI (Quick Path Interconnect) channels are a high-speed internetwork bus «point-to-point» between the processor and the chipset.

Conditions of use are the environmental and operational conditions obtained in the context of use of the system. Please refer to the PRQ for SKU-specific terms of use. Please refer to the Intel UC website (CNDA website)* for current terms of use information.

Maximum memory size refers to the maximum amount of memory supported by the processor.

Intel processors® Available in four different types: single channel, double channel, triple channel and flexible. The maximum supported memory speed may be lower when using multiple DIMMs per channel in products that support multiple memory channels.

The number of memory channels refers to the bandwidth for real-world applications.

Supported ECC memory indicates the processor’s memory support for error correction code. ECC memory is a type of system memory that can detect and correct common types of internal data corruption. Note that ECC memory support requires both processor and chipset support.

PCI Express version is the supported version of the PCI Express standard. Peripheral Component Interconnect Express (or PCIe) is a high-speed serial computer expansion bus standard for connecting hardware devices to a computer. Different versions of PCI Express support different data transfer rates.

The Microprocessor PCIe version is the version supported by the processor for PCIe lanes directly connected to the microprocessor. Peripheral Component Interconnect Express (or PCIe) is a high-speed serial computer expansion bus standard for connecting hardware devices to a computer. Different versions of PCIe Express support different data transfer rates.

Chipset/PCH PCIe version is the version supported by the PCH for PCIe lanes directly connected to the PCH. Peripheral Component Interconnect Express (or PCIe) is a high-speed serial computer expansion bus standard for connecting hardware devices to a computer. Different versions of PCIe Express support different data transfer rates.

PCI Express (PCIe) configurations describe the available PCIe lane configurations that can be used to connect to PCIe devices.

The PCI Express (PCIe) line consists of two pairs of differential signals: one for receiving data, the other for transmitting data, and is the main element of the PCIe bus. The maximum number of PCI Express lanes is the total number of lanes supported.

USB (Universal Serial Bus) is a standard technology for connecting peripheral devices to a computer.

SATA (Serial Advanced Technology Attachment) is a high-speed standard for connecting storage devices such as hard disks and optical drives to the motherboard.

Integrated LAN indicates the presence of built-in Intel Ethernet MAC or LAN ports built into the motherboard.

IDE (Integrated Drive Electronics) is an interface standard for connecting storage devices, which indicates that the disk controller is integrated into the drive rather than being a separate component on the motherboard.

A socket is a component that provides the mechanical and electrical connection between the processor and the motherboard.

Intel® RDT provides new levels of visibility and control over how shared resources such as last-level cache (LLC) and memory bandwidth are used by applications, virtual machines (VMs), and containers.

Intel Memory® Optane™ — is a revolutionary new class of non-volatile memory that sits between system memory and storage, improving system performance and responsiveness. Combined with Intel Storage Technology Driver® Rapid it seamlessly manages multiple tiers of storage by providing a single virtual disk to the operating system, ensuring that frequently accessed data resides in the fastest storage tier. Intel Memory® Optane™ requires special hardware and software configuration. Visit www.intel.com/OptaneMemory for configuration requirements.

Intel® Thermal Velocity Boost (Intel® TVB) is a function that opportunistically and automatically increases the clock frequency above the single-core and multi-core frequency of Intel technology® Turbo Boost depending on how much the processor runs below the maximum temperature and whether the turbo power is used. budget is available. Frequency gain and duration depend on workload, processor capabilities, and processor cooling solution.

Intel Technology® Turbo Boost Max 3.0 identifies the highest-performing processor cores and boosts the performance of those cores by increasing frequencies as needed, taking advantage of power headroom and thermal headroom.

Intel Technology® Hyper-Threading (Intel® HT Technology) provides two processing threads per physical core. Applications with more threads can do more work in parallel, completing tasks faster.

Intel architecture® provides 64-bit computing on servers, workstations, desktop and mobile platforms when combined with supporting software.¹ Intel 64 architecture improves performance by allowing systems to address more than 4 GB of both virtual and physical memory.

The instruction set refers to the basic set of commands and instructions that the microprocessor understands and can execute. The value shown indicates which Intel instruction set the processor is compatible with.

Instruction set extensions are additional instructions that can improve performance when performing the same operations on multiple data objects. These may include SSE (SIMD Streaming Extensions) and AVX (Advanced Vector Extensions).

Idle states (C-states) are used to save power when the processor is idle. C0 is the operating state, meaning the CPU is doing useful work. C1 is the first wait state, C2 is the second, etc., where more energy saving actions are taken for numerically higher C states.

Advanced Intel SpeedStep Technology® — is an industry-leading solution to deliver high performance while meeting the energy-saving needs of mobile systems. Traditional Intel SpeedStep Technology® switches voltage and frequency simultaneously between high and low levels depending on the processor load. Advanced Intel SpeedStep Technology® builds on this architecture using design strategies such as separation between voltage and frequency changes, and clock separation and recovery.

Intel Technology® QuickAssist provides security and compression acceleration capabilities used to improve performance and efficiency in the data center.

Intel Volume Manager® (VMD) provides a common and reliable method for hot-plugging and driving LEDs for NVMe-based SSDs.

Intel® Secure Key includes the RDRAND and RDSEED instructions, as well as the underlying hardware implementation used to generate high-quality keys for cryptographic protocols. For more information, see «ESV verification in product security certification: FIPS 140-3».

New Intel instructions® AES (Intel® AES-NI is a set of instructions that provide fast and secure encryption and decryption of data. AES-NI is useful for a wide range of cryptographic applications, such as applications performing bulk encryption/decryption, authentication, random number generation, and authenticated encryption.

Intel extensions® Software Guard Extensions (Intel® SGX) provide applications with the ability to create hardware-based trusted execution protection for their application’s sensitive procedures and data. Intel® SGX gives developers the ability to share their code and data in CPU-enhanced trusted execution environments (TEEs).

Intel Technology® Trusted Execution for Secure Computing is a universal set of hardware extensions to Intel processors and chipsets®, which enhance the digital office platform with security features such as controlled launch and secure execution. This creates an environment where applications can run in their own space, protected from all other software on the system.

Execute Disable Bit is a hardware-based security feature that can reduce exposure to viruses and malware attacks, and prevent malicious software from executing and spreading on a server or network.

Intel Technology® Device Protection with Boot Guard helps protect the system’s pre-OS environment from viruses and malware attacks.

Intel Technology® Virtualization (VT-x) allows one hardware platform to function as several «virtual» platforms. It provides improved manageability by limiting downtime and maintaining performance by isolating computing activity into separate partitions.

Intel Virtualization Technology® for Directed I/O (VT-d) continues existing virtualization support for IA-32 (VT-x) and Itanium processors® (VT-i), adding new support for I/O device virtualization. Intel VT-d can help end users improve system security, reliability, and I/O performance in virtualized environments.