ECS-160.003-18-1

Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us:   sales@allicdata.com

Crystals have a vast array of applications, ranging from timekeeping to radio frequency tuning. At the heart of each application is a unique arrangement of atoms that are arranged in an orderly fashion and interact with the electrical current in predictable ways. One type of crystal, known as ECS (Extended Crystal Structure) 160.003-18-1, is well-suited to applications that involve precision measuring and timing. This article will discuss the field of applications and working principles of ECS 160.003-18-1.

Applications

ECS 160.003-18-1 is used primarily in analog-to-digital and digital-to-analog converters (ADCs and DACs) as well as other precision timing and measuring instruments. It is reliable, cost-effective and very precise, making it an attractive option for many applications. Additionally, its performance is stable over the long term and it is immune to changes in temperature, humidity, and other environmental factors, making it suitable for many kinds of products.

ECS 160.003-18-1 crystals are also used in communication hardware, such as routers, switches, and other networked devices. The crystal can be used to generate a range of frequencies that are used to modulate and demodulate data signals, making it essential for high-speed communications. Additionally, they are used in RF filters and frequency synthesizers, which are necessary components of many types of communication systems.

Finally, ECS 160.003-18-1 crystals are also used in medical applications, particularly in the development of medical imaging technology. They can be used to stabilize the pulse sequence of an MRI machine, allowing for better resolution and accuracy. Additionally, they can be used to generate frequencies that can be used to probe and diagnose the body’s internal systems.

Working Principle

At the heart of the ECS 160.003-18-1 crystal’s operation is an arrangement of atoms that is highly reflective of external electrical fields. This arrangement, known as the Miller-Rabinovitz lattice, creates a series of cavity resonators. When an electrical field is applied to the crystal, the lattice absorbs energy, creating a physical distortion. This distortion causes the crystal to vibrate at a very precise frequency. This frequency can then be used as the foundation of an electronic circuit.

The vibrating crystal causes the atoms to align and interact with the electrical field in very predictable ways. This is what allows the crystal to produce reliable and accurate frequency outputs. The vibration of the crystal creates a wave that is reflective of the initial input, allowing it to be used as a frequency source for communication systems, ADCs and DACs, and other instrumentation.

The Miller-Rabinovitz lattice also allows the crystal to maintain its frequency even when exposed to changes in temperature, humidity, and other environmental factors. This means that it can be used in situations where accuracy and stability are paramount.

Conclusion

Crystal oscillators, such as ECS 160.003-18-1, are a key component in many electronic applications. They are reliable, cost-effective, and very accurate, making them an attractive choice for many applications. Additionally, they are immune to changes in temperature and humidity, making them suitable for long-term use.

At the heart of each crystal oscillator is a unique arrangement of atoms that are highly reflective of external electrical fields. This arrangement, known as the Miller-Rabinovitz lattice, creates a series of cavity resonators that the crystal interacts with in predictable ways. This allows the crystal to produce a very precise frequency at a stable rate, making it well-suited to many applications.

The specific data is subject to PDF, and the above content is for reference