An integrating ADC (Analog-to-Digital Converter) is a type of ADC that converts analog signals into digital representations using the principle of integration. It is also known as a dual-slope ADC. This type of ADC is particularly suited for accurate conversion of relatively slow-moving or stable analog signals.
Here's how the operation of an integrating ADC typically works:
Input Signal Conditioning: The analog input signal, which could be a voltage level, is first conditioned to ensure it falls within the appropriate range of the ADC. This might involve amplification, attenuation, or level shifting.
Start of Conversion (SOC): The conversion process begins with the start of a conversion cycle. This can be triggered manually or automatically, depending on the application.
Integration Phase:
a. Integration Ramp Generation: The ADC generates a known analog reference voltage (often called the "ramp" or "integrator input") that ramps up or down linearly over time. This voltage is typically generated using a digital-to-analog converter (DAC) and a timer.
b. Voltage Integration: The analog input signal is connected to the negative terminal of a comparator, and the integrating capacitor is connected to the positive terminal of the comparator. The comparator output is initially at a high state (logic 1).
c. Integrating Capacitor Discharge: The integrating capacitor starts discharging while it is connected to the negative terminal of the comparator.
Integration Time: The integration phase continues until the voltage across the integrating capacitor becomes equal to the analog input voltage. This time interval is known as the integration time and is determined by the rate at which the reference voltage ramp changes.
End of Integration: Once the voltage across the integrating capacitor matches the analog input voltage, the comparator output transitions from high to low (logic 1 to logic 0), marking the end of the integration phase.
Counter Timing: A counter, often driven by a clock signal, keeps track of the elapsed time during the integration phase. The counter value at the end of the integration phase is proportional to the input voltage.
Digital Conversion: The counter value, which corresponds to the integration time, is then converted into a digital representation using a binary encoding scheme. This digital value is the output of the ADC and represents the digital equivalent of the analog input signal.
Data Processing: The digital value can be further processed as needed, such as scaling, filtering, or additional computations, depending on the application.
The key advantage of integrating ADCs is their ability to reject noise and variations in the input signal during the integration phase. Since the integration time is determined by the ramping reference voltage, variations in the input signal that occur outside this time window have minimal impact on the accuracy of the conversion. This makes integrating ADCs suitable for applications where accuracy and noise rejection are critical, such as in instrumentation and measurement systems.