The DSO751SV 100.000MHZ is a crystal oscillator manufactured by KDS (Daishinku Corp). This oscillator provides a stable and precise clock signal at a frequency of 100.000 MHz. Crystal oscillators are crucial components in electronic circuits that require a reliable timing reference, commonly used in applications demanding high frequency accuracy and stability.

Applications

• High-speed microprocessors
• FPGA clocking
• High-speed data communication systems
• Network equipment
• High-resolution graphics cards

Features

• Precise frequency output: 100.000 MHz
• Excellent frequency stability
• Low phase noise
• Compact size
• Wide operating temperature range
• Surface Mount Device (SMD)

Benefits

• Accurate and stable timing for reliable high-speed system operation.
• Minimal timing jitter and phase noise, crucial for high-performance applications.
• Simple integration into circuit boards with SMD package.
• Stable performance across various operating conditions.
• High precision and reliability due to quality crystal element.

Detailed Specs

The DSO751SV 100.000MHZ is a surface-mount crystal oscillator that generates a stable clock signal at precisely 100 MHz. Frequency stability is a key parameter, usually specified in parts per million (PPM) over a specific temperature range. Its low phase noise characteristics minimize unwanted frequency variations, which is essential for applications such as high-speed data transfer and signal processing. The oscillator is built to function within a particular voltage range; it's vital to refer to its datasheet for the specific required voltage, such as 3.3V or 5V. Typical operating temperature falls between -40°C and +85°C, though the precise temperature range can be verified within the product documentation.

Because it offers a precise and steady clock signal, the oscillator is implemented in systems where consistent timing is paramount for optimal performance, including devices used for data communications and high-speed computing. The SMD package helps simplify integration into PCBs, enabling dense layouts.