Driven guard
A driven shield is a method of electrical shielding used to protect low-current circuits against leakage current, a driven shield is often referred to as a guard, especially when applied to PCB traces. It is used in situations where the tiny leakage of current through the insulating surfaces of a wire or PCB trace would otherwise cause error in the measurements or functionality of the device. The basic principle is to protect the sensitive wire with a surrounding guard that is held at the same voltage as the wire, if they are at the same voltage then there will be no current flow. This is typically achieved using a voltage buffer/follower that matches the guard voltage to the wire voltage. The leakage from the shield to other circuit elements is of little concern as it is being sourced from the buffer which has a low output impedance.
The technique is used in situations such as ECGs[2] and precision low-current measurement where leakage current would otherwise swamp or alter the measurement. Any situation in which the source to be measured has a very high output impedance is vulnerable to leakage current and if improved insulation is not practical then a driven shield may improve performance. Coaxial cable is well suited for use as a guard, if electromagnetic shielding is also required then triaxial cable should be used as depending on the type of buffer circuit any noise on the guard may be amplified in the output.[3]
The limiting factor for this method is the input impedance of the voltage buffer, the JFET or CMOS op-amps typically used may have input impedances of many tera-ohms which is typically sufficient. Care must also be taken to ensure there are no gaps in the guard or other paths by which leakage current may be encountered as this will defeat the system.
References
- ↑ Data Sheet AD8551/AD8552/AD8554 Figure 53. Top View of AD8552 SOIC Layout with Guard Rings
- ↑ , High-Quality Recording of Bioelectric Events - A. C. Metting van Rijn, A. Peper, C. A. Grimbergen
- ↑ , Shielding and Guarding - Alan Rich (AD application notes)