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Chapter 27. Queued Analog-to-Digital Converter (QADC)
27-73
Signal Connection Considerations
27.9.7 Analog Input Pins
Analog inputs should have low AC impedance at the pins. Low AC impedance can be
realized by placing a capacitor with good high frequency characteristics at the input signal
of the device. Ideally, that capacitor should be as large as possible (within the practical
range of capacitors that still have good high-frequency characteristics). This capacitor has
two effects:
realized by placing a capacitor with good high frequency characteristics at the input signal
of the device. Ideally, that capacitor should be as large as possible (within the practical
range of capacitors that still have good high-frequency characteristics). This capacitor has
two effects:
• It helps attenuate any noise that may exist on the input.
• It sources charge during the sample period when the analog signal source is a
• It sources charge during the sample period when the analog signal source is a
high-impedance source.
Series resistance can be used with the capacitor on an input signal to implement a simple
RC filter. The maximum level of filtering at the input pins is application dependent and is
based on the bandpass characteristics required to accurately track the dynamic
characteristics of an input. Simple RC filtering at the pin may be limited by the source
impedance of the transducer or circuit supplying the analog signal to be measured. (See
Section 27.9.7.2.”) In some cases, the size of the capacitor at the pin may be very small.
RC filter. The maximum level of filtering at the input pins is application dependent and is
based on the bandpass characteristics required to accurately track the dynamic
characteristics of an input. Simple RC filtering at the pin may be limited by the source
impedance of the transducer or circuit supplying the analog signal to be measured. (See
Section 27.9.7.2.”) In some cases, the size of the capacitor at the pin may be very small.
Figure 27-53 is a simplified model of an input channel. Refer to this model in the following
discussion of the interaction between the external circuitry and the circuitry inside the
QADC.
discussion of the interaction between the external circuitry and the circuitry inside the
QADC.
Figure 27-53. Electrical Model of an A/D Input Signal
F
, R
SRC
, and C
F
comprise the external filter circuit. C
P
is the internal
parasitic capacitor. C
SAMP
is the capacitor array used to sample and hold the input voltage.
V
I
is an internal voltage source used to provide charge to C
SAMP
during sample phase.
The following paragraphs provide a simplified description of the interaction between the
QADC and the user's external circuitry. This circuitry is assumed to be a simple RC
low-pass filter passing a signal from a source to the QADC input signal. These paragraphs
make the following assumptions:
QADC and the user's external circuitry. This circuitry is assumed to be a simple RC
low-pass filter passing a signal from a source to the QADC input signal. These paragraphs
make the following assumptions:
S1
AMP
RF
S3
C
SAMP
V
I
C
P
C
F
V
SRC
Internal Circuit Model
External Filter
V
SRC
= Source Voltage
= Internal Parasitic Capacitance
RF
CF
CF
CP
C
SAMP
= Sample Capacitor
VI
= Filter Impedance
= Filter Capacitor
= Filter Capacitor
= Internal Voltage Source During Sample and Hold
Source
R
SRC
R
SRC
= Source Impedance
S2