Manufacturer Part Number
P1014NSE5HFA
Manufacturer
NXP Semiconductors
Introduction
The P1014NSE5HFA is an embedded microprocessor from the QorIQ P1 Series, designed specifically for advanced networking and telecommunication systems.
Product Features and Performance
Single PowerPC e500v2 Core Processor
32-Bit Bus Width for efficient data transfer
Operating at a Speed of 800MHz
Integrated co-processors for Security tasks, including SEC 4.4
Supports DDR3 and DDR3L RAM Controllers enhancing memory compatibility
No Graphics Acceleration
Two Ethernet ports supporting speeds up to 10/100/1000Mbps
Two SATA ports with 3Gbps data transfer rate
One USB 2.0 + PHY interface for peripheral connectivity
Product Advantages
Enhanced security features including Boot Security, Cryptography, Random Number Generator, Secure Fusebox
High integration facilitating a reduced system footprint
Optimized for low-power consumption enhancing system efficiency
Key Technical Parameters
Core: PowerPC e500v2
Speed: 800MHz
RAM Controllers: DDR3, DDR3L
Ethernet: 10/100/1000Mbps (2)
SATA: SATA 3Gbps (2)
USB: USB 2.0 + PHY (1)
Operating Temperature Range: 0°C to 105°C
Quality and Safety Features
Tailored for high-reliability applications with extended operating temperature
Robust boot and cryptographic security features for data protection
Compatibility
Compatible with DDR3 and DDR3L memory types
Interface compatibility with DUART, I2C, MMC/SD, and SPI
Application Areas
Networking Equipment
Telecommunication Infrastructure
Industrial Control Systems
Data Management Systems
Product Lifecycle
Status: Obsolete
Note: Users may need to look for replacements or upgrades past this model due to the discontinuation of the P1014NSE5HFA. Consult NXP for potential alternatives.
Several Key Reasons to Choose This Product
Optimal choice for security and network-oriented applications due to advanced Ethernet and security features
Low power consumption conducive to energy-efficient design requirements
Wide operating temperature range suitable for harsh environments
Obsolete status ensures consideration of future upgrade pathways, enabling forward-planning for system design