The Maxim Integrated DS1010-80 is a highly versatile silicon delay line product that offers a precise, programmable delay of signals with minimal external components required. This device is part of the DS1010 series, which is renowned for its reliability and performance in timing management applications.

Features

• Programmable Delays: The DS1010-80 provides five equally spaced delays ranging from 4ns to 500ns per step, allowing for a total delay of up to 80ns to 10µs.
• High Precision: With its advanced silicon technology, the device ensures a delay accuracy of ±5% or ±2ns, whichever is greater, thereby guaranteeing precise timing for critical applications.
• Versatile Voltage Range: It operates over a wide supply voltage range of 4.5V to 5.5V, making it suitable for interfacing with various logic families.
• Low Power Consumption: The DS1010-80 is optimized for low power consumption, which is critical for power-sensitive designs.
• Temperature Stability: The delay is stable over the full temperature range of 0°C to 70°C, ensuring consistent performance under varying environmental conditions.

Applications

The Maxim Integrated DS1010-80 is ideal for a wide range of applications where precise signal timing is paramount. These include:

• Timing adjustment in digital circuits
• Signal synchronization and skew compensation
• Waveform generation and shaping
• Pulse-width modulation and delay-based modulation schemes
• System calibration and timing fine-tuning in embedded systems

Easy Integration

The DS1010-80 is designed for simple integration into existing designs thanks to its industry-standard 14-pin DIP (Dual In-line Package) or SO (Small Outline) package. Its pin-compatible nature with other devices in the DS1010 series allows for easy scalability or adjustments to timing requirements without significant design changes.

With Maxim Integrated's commitment to quality and long-term reliability, the DS1010-80 is a smart choice for designers looking to add precise timing control to their systems with minimal design overhead and maximum flexibility.