In the era of the Internet of Things (IoT), precise clock signals are the 'life pulse' of smart devices. Whether it's IoT sensors transmitting data in real-time or high-speed communication 5G modules, once the clock becomes inaccurate, the consequences range from data corruption to complete system failure. Temperature fluctuations, voltage changes, mechanical stress—these seemingly minor disturbances constantly challenge the stability of electronic equipment.

Is your device facing these issues?

Frequency drift in wide temperature environments, causing communication interruptions?

Limited by circuit board space, making it difficult to deploy high-performance components?

Battery-powered devices frequently running low on power due to high power consumption?

EPSON—a global leader in frequency control components—responds to these challenges with an innovative solution: The TG5032CFN Temperature-Compensated Crystal Oscillator (TCXO), a clock component that integrates ultra-high precision, ultra-low power consumption, and a miniature package, born for demanding applications!

Why choose the TG5032CFN? Three core advantages define the industry benchmark

1. Exceptional Temperature Stability Deviation (±0.1 ppm)

Within the room temperature ±25°C range, frequency deviation is strictly controlled within ±0.1 ppm, completely solving the temperature drift problem.

Technical Support: Built-in high-precision temperature sensor and adaptive compensation algorithm real-time offset crystal frequency deviation, ensuring stable operation of industrial equipment in extreme cold and heat, and preventing GPS module positioning offset.

2. Disruptive Low Power Consumption (5.0mA @3.3V)

Typical power consumption is only 5.0mA, more than 30% lower than traditional TCXOs, significantly extending the battery life of IoT sensors and wearable devices.

Scenario Value: Asset trackers powered by button cells can see their battery life extended by months; smartwatches can monitor all day without worrying about power.

3. Miniaturized Package (5.0mm × 3.2mm)

Uses the industry-standard 5.0x3.2mm package, with an area smaller than a coin, freeing up space for high-density PCB design.

Application Breakthrough: Facilitates the slim design of 5G communication modules, allowing integration into the core boards of micro devices like medical electronic probes.

Key Parameters at a Glance

Enabling Cutting-Edge Application Scenarios

IoT Terminals: Wireless sensors, smart meters, environmental monitors, fearless of drastic temperature changes in the field.

5G Communication Modules: Ensures signal synchronization for Cat-M/NB-IoT narrowband communication, reducing bit error rates.

Wearable Devices: Smart bracelets accurately record sports data with power consumption only 60% of traditional solutions.

Industrial Control: PLC controllers operate stably for 100,000 hours without clock drift in high-temperature workshops.

Medical Electronics: Portable ECG devices rely on low power consumption for 72-hour continuous monitoring.

EPSON Quality: Full-Chain Reliability from Crystal Wafer to Finished Product

Technical DNA: Based on QMEMS technology (Quartz + MEMS), achieving micron-level precision processing at the silicon wafer level.

Fully Automated Production: Cutting, packaging, and testing are completed in clean rooms, with a first-pass yield of over 99.95%.

25-Year Lifespan Verification: Passes the 85°C/85% RH dual 85 accelerated aging test, with a failure rate of<1 FIT.

Compliance Assurance: Complies with RoHS and halogen-free directives.