AMD Turion™ 64 Mobile Technology Product Data Sheet

32816 Rev. 3.05 September 2006

Socket S1g1 Processor Specific Features

• Refer to the Socket S1g1 Processor Functional Data Sheet, order# 31731, for functional and mechanical details of socket S1g1 processors. Refer to the AMD NPT Family 0Fh Processor Electrical Data Sheet, order# 31119, for electrical details of socket S1g1 processors.

Packaging

Electrical Interfaces

HyperTransport™ technology: LVDS-like differential, unidirectional

DDR2 SDRAM: SSTL_1.8 per JEDEC specification

Clock, reset, and test signals also use DDR2 SDRAM-like electrical specifications

638-pin lidless micro PGA package

1.27-mm pin pitch

26 x 26 pin grid array

35 mm x 35 mm organic substrate

Compliant with RoHS (EU Directive 2002/95/EC) with lead used only in small amounts in specifically exempted applications

Integrated Memory Controller

Low-latency, high-bandwidth

128-bit DDR2 SDRAM controller operating at up to 333 MHz

Supports up to two unbuffered SO-DIMMs

Power Management

Multiple low-power states.

System Management Mode (SMM)

ACPI compliant, including support for processor performance states.

AMD PowerNow!™ technology is designed to dynamically switch between multiple low-power states based on application performance requirements.

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AMD 64 specifications Socket S1g1 Processor Specific Features, Packaging Electrical Interfaces

64 specifications

AMD64 is a 64-bit architecture developed by Advanced Micro Devices (AMD) as an extension of the x86 architecture. Introduced in the early 2000s, it aimed to offer enhanced performance and capabilities to powering modern computing systems. One of the main features of AMD64 is its ability to address a significantly larger amount of memory compared to its 32-bit predecessors. While the old x86 architecture was limited to 4 GB of RAM, AMD64 can theoretically support up to 16 exabytes of memory, making it ideal for applications requiring large datasets, such as scientific computing and complex simulations.

Another key characteristic of AMD64 is its support for backward compatibility. This means that it can run existing 32-bit applications seamlessly, allowing users to upgrade their hardware without losing access to their existing software libraries. This backward compatibility is achieved through a mode known as Compatibility Mode, enabling users to benefit from both newer 64-bit applications and older 32-bit applications.

AMD64 also incorporates several advanced technologies to optimize performance. One such technology is the support for multiple cores and simultaneous multithreading (SMT). This allows processors to handle multiple threads concurrently, improving overall performance, especially in multi-tasking and multi-threaded applications. With the rise of multi-core processors, AMD64 has gained traction in both consumer and enterprise markets, providing users with an efficient computing experience.

Additionally, AMD64 supports advanced vector extensions (AVX), which enhance the capability of processors to perform single instruction, multiple data (SIMD) operations. This is particularly beneficial for tasks such as video encoding, scientific simulations, and cryptography, allowing these processes to be executed much faster, thereby increasing overall throughput.

Security features are also integrated within AMD64 architecture. Technologies like AMD Secure Execution and Secure Memory Encryption help protect sensitive data and provide an enhanced security environment for virtualized systems.

In summary, AMD64 is a powerful and versatile architecture that extends the capabilities of x86, offering enhanced memory addressing, backward compatibility, multi-core processing, vector extensions, and robust security features. These innovations have positioned AMD as a strong competitor in the computing landscape, catering to the demands of modern users and applications. The continuous evolution of AMD64 technology demonstrates AMD's commitment to pushing the boundaries of computing performance and efficiency.