Characteristics of Epson SG-8200CG Programmable Crystal Oscillator

In modern electronic devices, clock signals play a crucial role in ensuring the synchronous operation of various components within the system, guaranteeing stable data transmission and efficient processing. Choosing a suitable clock source is crucial for application scenarios that require high precision and reliability. The Epson SG-8200CG programmable crystal oscillator stands out among numerous application fields due to its outstanding performance and flexible configuration options. Whether it is industrial automation, automotive electronics, communication equipment, or consumer electronics, SG-8200CG can provide high-quality clock solutions to assist in the stable operation of the system.

1、 Accurate frequency output

The SG-8200CG programmable crystal oscillator has demonstrated remarkable strength in frequency accuracy. It has a wide frequency range from 1.2MHz to 170MHz, and can flexibly set the required frequency according to different application scenarios, meeting the diverse needs of electronic devices. Within the conventional operating temperature range of -40 ° C to+105 ° C, the frequency tolerance can be precisely controlled within ± 15 × 10 ⁻⁶, which means that even under harsh environmental temperature changes, the crystal oscillator can still stably output accurate frequency, providing a solid guarantee for the stable operation of the equipment. Whether it is the manipulation of precision instruments in the field of industrial control or the precise modulation and demodulation of signals in communication equipment, its stable frequency output is like a compass, ensuring that every data processing link can be carried out in an orderly manner, effectively avoiding system failures or performance degradation caused by frequency deviation, greatly improving the reliability and stability of the entire electronic system.

2、 Excellent temperature characteristics

Faced with complex and ever-changing environmental temperatures, SG-8200CG showed no fear. It has excellent temperature adaptability, and its special design and material processing inside enable the crystal oscillator to effectively resist the impact of temperature rise on frequency stability in high temperature environments. When the temperature rises to+125 ° C, the frequency tolerance can still be maintained within a reasonable range, which makes it stand out in some special industrial application scenarios, such as automated production lines for high-temperature operations and electronic control systems in car engine compartments. In low-temperature environments, such as monitoring equipment in cold polar regions or low-temperature storage warehouses, it can also work stably, maintain frequency accuracy, and ensure that the equipment will not have abnormal clock signals even under severe cold conditions, truly achieving reliable operation throughout the entire temperature range and safeguarding the normal operation of electronic devices in various extreme environments.

3、 Low jitter performance

In the world of signal transmission, jitter is the enemy that affects signal quality. The SG-8200CG programmable crystal oscillator has become the guardian of signal purity with its excellent low jitter performance. At a frequency of 125MHz, the typical phase jitter can be as low as 1.1ps, and this small jitter value has immeasurable value in high-speed data transmission, precision measuring instruments, and communication systems that require extremely high clock signal quality. In high-speed communication links, low jitter crystal oscillators can ensure the integrity and accuracy of data signals, greatly reducing the bit error rate and enabling fast and error free transmission of data between different devices. In high-precision measuring instruments, it can provide a stable and reliable clock reference for measurement, effectively reducing measurement errors caused by clock jitter, making measurement results more accurate and reliable, and providing strong technical support for scientific research, engineering design, and other fields.

4、 Compact packaging design

With the increasing trend of miniaturization in electronic devices, the spatial layout of internal components is becoming more compact. The SG-8200CG adopts a sophisticated 2.0 × 1.6mm package size, which allows it to be easily placed in limited circuit board space. In application scenarios such as smartphones, wearable devices, and IoT modules that require extremely strict space requirements, its advantages are fully demonstrated. Not only does it free up valuable space for other functional components, allowing the device to integrate more functions and features, but it also facilitates the design and layout of circuit boards, improving production efficiency and product manufacturability. Its compact packaging form perfectly matches the miniaturization and lightweight design concept of modern electronic devices, becoming a powerful assistant in promoting the development of electronic devices towards smaller, more refined, and stronger directions.

5、 Flexible programmability

The programmable features of SG-8200CG have opened a door to infinite possibilities for electronic engineers. It allows users to freely set the desired clock frequency within a wide frequency range according to specific application requirements, without relying on fixed frequency crystal oscillator products. This flexibility is particularly important in the product development process, as it can greatly shorten the product design cycle and reduce research and development costs. For example, in a multifunctional smart device, clock signals of different frequencies may be required to drive different functional modules. SG-8200CG can easily achieve this requirement by programming each module to provide the appropriate clock frequency, making the collaborative work of various parts of the entire device smoother and more efficient. At the same time, when upgrading or expanding products, simply reprogram the crystal oscillator to meet new frequency requirements without the need to replace hardware, greatly improving the scalability and adaptability of the product, providing strong support for the rapid iteration and innovative development of electronic devices.