Manufacturer Part Number
P1022NSE2HFB
Manufacturer
nxp-semiconductors
Introduction
The P1022NSE2HFB is part of NXP Semiconductors' QorIQ P1 series of embedded microprocessors, designed for advanced communication and networking applications.
Product Features and Performance
Dual-core PowerPC e500v2 processor at 1.055GHz
Supports DDR2 and DDR3 RAM controllers
Integrated security co-processor (SEC) for enhanced security
Two SATA 3Gbps interfaces for storage applications
Dual USB 2.0 + PHY interfaces for peripheral connectivity
Two 10/100/1000Mbps Ethernet ports for networking
Surface mount, 689-BBGA exposed pad package
Product Advantages
Enhanced security features including cryptography and random number generator
High-speed processing capability with dual-core architecture
Broad connectivity options including Ethernet, SATA, and USB
Supports legacy and modern memory standards (DDR2 and DDR3)
Key Technical Parameters
Core Processor: PowerPC e500v2, 32-Bit
Speed: 1.055GHz
Co-processors/DSP: Security; SEC
RAM Controllers: DDR2, DDR3
Ethernet: 10/100/1000Mbps (2)
SATA: SATA 3Gbps (2)
USB: USB 2.0 + PHY (2)
Operating Temperature: 0°C ~ 105°C (TA)
Quality and Safety Features
High operational temperature range ensuring reliability in various environments
Advanced security features for data protection
Compatibility
Compatible with various DDR2 and DDR3 memory modules
Interface flexibility for wide range peripheral and storage options
Application Areas
Networking equipment
Communication infrastructure
Advanced embedded systems
Product Lifecycle
Obsolete status, indicating the end of production and the need for customers to seek replacement or upgrade options
Several Key Reasons to Choose This Product
Dual-core performance provides increased processing power for demanding applications
Comprehensive security features safeguard sensitive information
Wide range of connectivity options enhances system flexibility and functionality
Support for both DDR2 and DDR3 memory allows for versatile memory configurations
Obsolete status necessitates consideration of future-proofing and upgrade paths in system design