NB3N51054DTR2G

Overview

• Category: Integrated Circuit
• Use: Clock Generator and Buffer
• Characteristics: Low jitter, high frequency, low power consumption
• Package: 8-pin SOIC (Small Outline Integrated Circuit)
• Essence: Clock generation and buffering for various electronic devices
• Packaging/Quantity: Tape and Reel, 2500 units per reel

Specifications and Parameters

• Input Voltage Range: 1.65V to 3.6V
• Output Frequency Range: 10MHz to 200MHz
• Supply Current: 5mA (typical)
• Operating Temperature Range: -40°C to +85°C

Pin Configuration

The NB3N51054DTR2G has the following pin configuration:

┌───┬───┐ │ 1 │ 8 │ │ 2 │ 7 │ │ 3 │ 6 │ │ 4 │ 5 │ └───┴───┘

Pin Description: 1. VDD: Power supply voltage input 2. GND: Ground reference 3. OUT0: Differential output 0 4. OUT0#: Complementary differential output 0 5. OUT1: Differential output 1 6. OUT1#: Complementary differential output 1 7. SEL: Select input for frequency multiplication factor 8. REF: Reference clock input

Functional Characteristics

• Generates low-jitter clock signals with selectable frequency multiplication factor
• Provides differential outputs for improved noise immunity
• Supports a wide range of input voltages for compatibility with different systems
• Low power consumption for energy-efficient operation

Advantages and Disadvantages

Advantages: - Low jitter for accurate timing in sensitive applications - High-frequency range for versatile use in various electronic devices - Low power consumption for energy-efficient operation

Disadvantages: - Limited to 8-pin SOIC package, may not be suitable for all applications - Requires an external reference clock input

Applicable Range of Products

The NB3N51054DTR2G is commonly used in the following applications: - Communication systems - Networking equipment - Data storage devices - Industrial automation - Consumer electronics

Working Principles

The NB3N51054DTR2G operates by taking a reference clock input and generating multiple clock signals with selectable frequency multiplication factors. These clock signals can be used to synchronize various components within electronic systems.

Detailed Application Field Plans

1. Communication Systems: The NB3N51054DTR2G can be used to generate clock signals for data transmission and reception in communication systems, ensuring accurate timing and synchronization.
2. Networking Equipment: This IC can provide clock signals for network switches, routers, and other networking equipment, enabling reliable data transfer and synchronization.
3. Data Storage Devices: Clock generation and buffering are crucial for data storage devices such as hard drives and solid-state drives. The NB3N51054DTR2G can ensure precise timing for data read and write operations.
4. Industrial Automation: In industrial automation systems, the IC can be used to synchronize various components, such as sensors, actuators, and controllers, ensuring smooth operation and precise timing.
5. Consumer Electronics: Clock signals generated by the NB3N51054DTR2G are essential for consumer electronics like TVs, smartphones, and gaming consoles, providing accurate timing for various functions and features.

Detailed Alternative Models

Some alternative models to the NB3N51054DTR2G include: - NB3N551MNR2G - NB3N5573MNR2G - NB3N5575MNR2G - NB3N5577MNR2G - NB3N5579MNR2G

5 Common Technical Questions and Answers

1. Q: What is the maximum output frequency of the NB3N51054DTR2G? A: The maximum output frequency is 200MHz.

2. Q: Can I use a lower voltage than 1.65V as the input voltage? A: No, the minimum input voltage should be 1.65V for proper operation.

3. Q: Does the IC support frequency multiplication? A: Yes, the IC has a selectable frequency multiplication factor controlled by the SEL pin.

4. Q: What is the typical supply current of the NB3N51054DTR2G? A: The typical supply current is 5mA.

5. Q: Is the NB3N51054DTR2G suitable for automotive applications? A: No, the operating temperature range of -40°C to +85°C may not be sufficient for automotive environments.

This encyclopedia entry provides an overview of the NB3