高精度的SMD振蕩器深受智能家居應(yīng)用的追棒ECS-8FMX-080-T，在比較石英和 MEMS 的頻率與溫度穩(wěn)定性時。您會看到基于石英貼片晶振的振蕩器遵循 AT 晶體的連續(xù)三次曲線，并在 -40°C ~ +85°C 范圍內(nèi)達到 ±25 ppm，這對于大多數(shù)應(yīng)用來說已經(jīng)足夠了。

查看 MEMS 圖，它似乎具有更好的頻率與溫度特性，但如果仔細觀察，您會發(fā)現(xiàn)該圖顯示了在調(diào)整 PLL 分頻比以補償溫度變化時引起的頻率跳躍。這會導(dǎo)致顯著的頻率跳躍，以補償 MEMS 諧振器的顯著頻率漂移（30 ppm/°C 或 3750 ppm -40°C ~ +85°C）

Manufacturer Part Number原廠代碼	Manufacturer品牌	Series型號	Frequency 頻率	Operating Temperature 工作溫度
ECS-8FM-024-TR	ECS晶振	ECS-8F	2.4576MHz	-40°C ~ 85°C
ECS-8FM-143-TR	ECS晶振	ECS-8F	14.31818MHz	-40°C ~ 85°C
ECS-8FM-143-TR	ECS晶振	ECS-8F	14.31818MHz	-40°C ~ 85°C
ECS-8FM-143-TR	ECS晶振	ECS-8F	14.31818MHz	-40°C ~ 85°C
ECS-8FMX-080-TR	ECS晶振	ECS-8FX	8MHz	-40°C ~ 85°C
ECS-8FMX-080-TR	ECScrystal晶振	ECS-8FX	8MHz	-40°C ~ 85°C
ECS-8FMX-080-TR	ECS晶振	ECS-8FX	8MHz	-40°C ~ 85°C
ECS-8FA3X-245.7-TR	ECS晶振	ECS-8FX	24.576MHz	-40°C ~ 85°C
ECS-8FA3X-245.7-TR	ECS晶振	ECS-8FX	24.576MHz	-40°C ~ 85°C
ECS-8FA3X-245.7-TR	ECS晶振	ECS-8FX	24.576MHz	-40°C ~ 85°C
ECS-8FM-040-TR	ECS晶振	ECS-8F	4MHz	-40°C ~ 85°C
ECS-8FM-040-TR	ECS晶振	ECS-8F	4MHz	-40°C ~ 85°C
ECS-8FM-040-TR	ECS晶振	ECS-8F	4MHz	-40°C ~ 85°C
ECS-8FMX-040-TR	ECS晶振	ECS-8FX	4MHz	-40°C ~ 85°C
ECS-8FMX-040-TR	ECS晶振	ECS-8FX	4MHz	-40°C ~ 85°C
ECS-8FMX-040-TR	ECS晶振	ECS-8FX	4MHz	-40°C ~ 85°C

高精度的SMD振蕩器深受智能家居應(yīng)用的追棒ECS-8FMX-080-T，ECS利用自身優(yōu)勢開發(fā)這款有源晶振ECS-8FMX-080-TR，ECS-8FMX (5V)和ECS-8FA3X (3.3V)是CMOS兼容的j引線SMD振蕩器。8F系列采用了低功耗CMOS集成電路的成本效益包適合回流焊接。

石英在溫度范圍內(nèi)比 MEMS 更穩(wěn)定，并提供高“Q”性能。基于石英的振蕩器不需要采用溫度補償來在所需溫度范圍內(nèi)保持低至 ±10 ppm 的穩(wěn)定性。如果需要更好的穩(wěn)定性，您可以向石英晶體振蕩器添加溫度補償，并在整個溫度范圍內(nèi)獲得低至 0.5 ppm 的穩(wěn)定性。

When comparing the Frequency vs. Temperature stability of quartz and MEMS. You see that the quartz-based oscillator follows the continuous cubic curve of an AT crystal and achieves ±25 ppm from -40°C ~ +85°C, which is good enough for most applications.

Looking at the MEMS plot it appears to have better frequency vs. temperature characteristics, but if you look closely you can see that the plot shows frequency jumps caused when the PLL division ratio is adjusted to compensate for changes in temperature. This causes significant Frequency jumps in order to compensate for the considerable frequency drift of the MEMS resonator (30 ppm/°C or 3750 ppm -40°C ~ +85°C)

Quartz is much more stable over temperature than MEMS and offers high “Q” performance. The quartz-based oscillator does not need to employ temperature compensation to maintain stabilities as low as ±10 ppm over the required temperature range. If better stabilities are required, you can add temperature compensation to a quartz oscillator and get stabilities as low as 0.5 ppm over temperature.