资 源 简 介
介绍
此应用说明程序校准模拟到数字转换器(ADC−−)上belasigna 300,并讨论了何时以及为什么这种标定方法推荐。
目标受众是正在建设的客户高−高保真音频应用中使用belasigna 300。
背景
模拟数字转换BelaSigna 300,运算放大器(OP−AMPS)用于输入300阶段的belasigna产生直流偏移,在∑ΔADC−闭环积累。
这种积累产生ADC输出振荡周期性的,这可能会导致音调和/或颠簸,在噪音地板。噪声中这些凸块的频率地板直接关系到ADC的频率输出振荡,可以通过调整直流ADC本身的偏移量。直流偏移可以选择将突出物放在噪声地板上取样或可听频率范围。关于这个直流的更多细节,偏移累积表现为噪声中的凸起地板,参见附录A.每个ADC的直流偏移的值是可配置的通过专用寄存器。确定理想直流偏移值(可每300 belasigna独特并实现最佳性能,ADC可执行校准过程。通常这将在生产线进行,校准存储在连接到belasigna SPI EEPROM的值300。然后在每次启动时加载这些值。belasigna 300提供了4个独立的,16−点,8x在−采样的模拟到数字转换器−−。这些通道有8种可能的增益设置(0,12,15,18,21,24,27,和30分贝),每个通道的增益设置可能有唯一的校准值。因此,总共有32种可能,校准值是必需的一个完整的系统校准。根据应用程序,但是,它可能更高效的校准ADC只有预−放大器增益设置。
When Is ADC CalibraTIon Necessary?
The severity of the tones in the noise floor depends on the rate of DC offset accumulaTIon, and the sampling rate at which the system is configured. The absolute worst case occurs when the fundamental frequency of oscillaTIon is lower than the one−half of the sampling rate of the system (Fs/2)。 This can produce tonal spikes in the frequency spectrum as high as −70 dBFS. While this is quite rare for typical audio sampling rates, tones of this magnitude may be audible when low preamplifier gain values are used and for this reason calibraTIon is recommended.
In general, calibration is recommended for most audio applications; however it may be beneficial to ignore the calibration procedure if your product is using a microphone as a signal source, as any ADC tones may be masked by the self−noise of the microphones.
