編碼ECS-2033-160-BN是一款具有核心競爭力的超小性SMD振蕩器，振蕩器可以有幾種不同類型的與之相關的諧振器。其中最多產和表現最好的是石英晶振。您還可以找到使用基于陶瓷、SAW[1]或 MEMS[2]的諧振器的振蕩器作為工作頻率的起點。它們使用機械振動或調諧腔來產生時鐘信號。在石英基振蕩器的情況下，石英材料的成分以及晶體切割的角度使得這種類型的振蕩器在很寬的溫度范圍內非常精確和穩定。制造振蕩器級晶體空白的過程非常耗時，需要許多步驟來確保始終如一的高質量有源晶振產品，但它們提供的穩定性比RC振蕩器要好得多。

編碼ECS-2033-160-BN是一款具有核心競爭力的超小性SMD振蕩器，振蕩電路背后的原理是穩定的穩態輸出信號。實現此目的的一種方法是使用正反饋循環。在這里，輸出電壓的一部分被反饋到輸入，沒有凈相移，因此增強了輸出信號。然后信號被放大并再次環回，導致輸出信號增長。反饋回路中的增益需要控制為單位增益，否則信號將被削波和失真。

Manufacturer Part Number原廠代碼	Manufacturer品牌	Series型號	Frequency 頻率	Operating Temperature 工作溫度
ECS-VXO-73-19.440-TR	ECS晶振	ECS-VXO-73	19.44MHz	-10°C ~ 70°C
ECS-VXO-73-27.00-TR	ECS晶振	ECS-VXO-73	27MHz	-10°C ~ 70°C
ECS-VXO-73-27.00-TR	ECS晶振	ECS-VXO-73	27MHz	-10°C ~ 70°C
ECS-VXO-73-27.00-TR	ECS晶振	ECS-VXO-73	27MHz	-10°C ~ 70°C
ECS-2033-160-BN	ECS晶振	ECS-2033	16MHz	-40°C ~ 85°C
ECS-2033-160-BN	ECS晶振	ECS-2033	16MHz	-40°C ~ 85°C
ECS-2033-160-BN	ECS晶振	ECS-2033	16MHz	-40°C ~ 85°C
ECS-2033-240-BN	ECS晶振	ECS-2033	24MHz	-40°C ~ 85°C
ECS-2033-240-BN	ECS晶振	ECS-2033	24MHz	-40°C ~ 85°C
ECS-2033-240-BN	ECS晶振	ECS-2033	24MHz	-40°C ~ 85°C
ECS-2033-130-BN	ECS晶振	ECS-2033	13MHz	-40°C ~ 85°C
ECS-2033-130-BN	ECS晶振	ECS-2033	13MHz	-40°C ~ 85°C
ECS-2033-130-BN	ECS晶振	ECS-2033	13MHz	-40°C ~ 85°C
ECS-2033-250-BN	ECS晶振	ECS-2033	25MHz	-40°C ~ 85°C
ECS-2033-250-BN	ECS晶振	ECS-2033	25MHz	-40°C ~ 85°C
ECS-2033-250-BN	ECS晶振	ECS-2033	25MHz	-40°C ~ 85°C

ECS利用自身強大的生產力,開發這款ECS-2033-160-BN，ECS-2025 (2.5V)和ECS-2033 (3.3V)超小型SMD振蕩器。非常適合當今的高密度應用。

Oscillators can have several different types of resonators associated with them. The most prolific and best performing of these is quartz. You may also find oscillators that use ceramic, SAW[1]or MEMS[2]based resonators to be the starting point for the operational frequency. They use mechanical vibration or tuned cavities to generate the clock signal. In the case of the quartz-based oscillator, the composition of the quartz material, and the angles that the crystal are cut makes this type of oscillator very precise and stable over a wide temperature range. The process for making oscillator grade crystal blanks is time consuming, with many steps to ensure consistent high-quality product, but they offer vastly superior stability over RC oscillators.

The principle behind the oscillator circuit is a stable steady state output signal. One way to accomplish this is by using a positive feedback loop. Here a portion of the output voltage is feedback to the input with no net phase shift, so reinforcing the output signal. The signal is then amplified and looped back again causing the output signal to grow. The gain in the feedback loop needs to be controlled to unity gain, otherwise the signal will be clipped and distorted.

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