Ground bounce originates from transient currents flowing through the power distribution impedance.  Simulation tools typically embed ground bounce into supply noise giving the false impression that the ground net is clean and only the supplies (positive and negative) move with the respect to the ground.  Postprocessing of simulation results can further extract/compute the ground bounce noise.

Ground bounce may affect the bandgap output since this output is a voltage referenced to ground.  Ground electric potential changes across the circuit and these differences may couple into the bandgap reference distribution circuitry.

Cosmin Iorga, Ph.D.
NoiseCoupling.com
http://www.noisecoupling.com

If I understand correctly what you asked me, ground is typically distributed as a plane or mesh across all circuits.  In both cases there is a 2-dimmensional distributed impedance associated to the ground (and to the power supplies as well).  This impedance results from the finite resistance of the conductive material and the loop inductance.  Ground current flow has also a 2-dimensional distribution, and due to V=IR drops it creates an electric potential distribution.  Dynamic ground currents generate dynamic electric potential distribution, so each device connected to ground may see a different potential than the expected zero Volts.

Cosmin Iorga, Ph.D.
NoiseCoupling.com
http://www.noisecoupling.com

You can not generalize it. It will be unique to the circuits and their layout.

ci wrote on Aug 18^th, 2009, 4:13pm:


There is another more insidious effect. AC currents in bipolar are nonlinear, so the DC value of the current changes with the amplitude of the AC current. The net effect is that the DC output of the bandgap will change depending on the amplitude of the AC noise. The AC current can be coupled in from the base/collector capacitance of the PNP, or from other sources. This is in addition to the effect you describe. It is frequency dependent.

Many an engineer have freaked out upon seeing their dear bandgap voltage drop 50 mV when the noisy circuitry is switched on.