Crystals have been used for centuries to keep time and measure frequencies. In the last century, scientists have developed a range of crystals, including the 9C-16.000MEEJ-T. This type of crystal is widely used in many applications due to its durability, stability, and accuracy.
The 9C-16.000MEEJ-T crystal is a quartz oscillator that features a 0.045% stability over the -30°C to 85°C temperature range. It is a low-cost, low-power crystal with excellent accuracy and wide dynamic range. It is also highly resistant to mechanical and environmental factors, including impacts, shocks, and large temperature variations.
These crystals are commonly used in oscillators, RTCs (real-time clocks) and synchronization applications. They are also used in microprocessors, components for telecom, and high-performance clocks. The 9C-16.000MEEJ-T crystal is also suitable for use in quartz crystal filters and timer circuits.
The working principle of the 9C-16.000MEEJ-T crystal is relatively simple. It uses the natural vibration of quartz and the piezoelectric effect to produce an accurate, electrical signal. Piezoelectricity is the ability of certain materials to generate an electrical signal when subjected to mechanical stress, and crystals use this property to oscillate at a precise frequency and produce a stable, electrical signal.
The 9C-16.000MEEJ-T crystal is placed between two electrodes, which form a capacitor. An electrical field is then applied across these electrodes. The crystal begins to vibrate due to the applied electrical field and this energy is returned in the form of an electrical current, which is then transformed into an oscillating electrical signal.
The frequency of this signal is determined by the shape, size and construction of the crystal. The 9C-16.000MEEJ-T crystal is designed in such a way that it produces a highly accurate, stable frequency of 16.000MHz. This frequency is then used to keep time, measure frequencies, or synchronize the operation of other components in the system.
The 9C-16.000MEEJ-T crystal is a highly accurate and reliable component. Its stability over a wide temperature range and excellent accuracy make it ideal for a variety of applications, ranging from oscillators and RTCs to synchronization applications. Its wide dynamic range also makes it suitable for use in microprocessors and telecom components.