The second source of noise coupling is over the substrate. Because
the substrate offers a relatively high impedance to ground, noise
generated in one section of the circuit can be propagated through
the substrate to other parts of the chip. This noise can then be
capacitively coupled into the active part of an analog circuit.
High impedance nodes
as well as
input nodes are particularly sensitive to capacitive coupling.
Figure 6.7: Using well as shield.
The capacitive coupling into circuit elements (resistors and capacitors) and sensitive signal lines, can be reduced with the use of shielding layers. To provide the maximum possible decoupling, the shielding layer should have the lowest possible impedance to a quiet power supply.
The most commonly used shielding is to place a well under capacitors
and resistors. Figure 6.7 shows the implementation
of a resistor and a capacitor
using a well as shielding layer. The
well below the resistor and capacitor serve to attenuate the noise
coupling from the substrate to poly-silicon or metal layer.
Sensitive analog lines should be connected, whenever possible, in aluminium. This permits the use of a poly-silicon layer below the metal line as a shielding layer. The poly-silicon having a lower impedance than the well, provides a better attenuation of capacitively coupled noise.
The prudent use of well and substrate contacts helps to keep the active
silicon free from noise in the analog sections of the circuit. Careful
consideration should be used to determine where and when to use such
contacts. For very sensitive applications, the use of dual VSS
lines internal
to the cells is generally recommended[O'L91]. One VSS line
is used to supply the cell with current, and a second line is used to
connect the substrate. The two supplies are then led to separate pads,
which helps to prevent noise on the digital supply lines from entering
the substrate.