The Diamond Plot


My signal is within the instrumentation amplifier’s specified input voltage range, but the output seems saturated. What’s happening? Is the part broken?

RAQ:  Issue 107


On February 18, 2013, a spectacular and successful diamond heist was carried out in about five minutes, while loading the cargo onto an aircraft headed from Brussels to Zurich. An estimated value of $350 million makes it one of the largest diamond heists of all time. With thieves disguised as police officers (down to the armbands), an elaborate plot was executed quickly and with high precision, similar to what would be seen in a Hollywood movie. The passengers didn’t notice until everyone had to disembark the airplane. The robbery started an international manhunt to bring the burglars to justice.

Those of us working with electronics need to be concerned with a different diamond plot. When using in-amps, designers often observe strange phenomena. The problem is sometimes accurately explained as “the output is saturated,” but other times the description can be a little more cryptic: “the gain error is very high,” or “the amplifier is very nonlinear,” or simply “it doesn’t work when it should.” We don’t have a flow chart to solve customer problems, but if we had one, “check the diamond plot” would come right after “make sure the part is powered up.”

In this context, the diamond plot, often found in the data sheet, shows an in-amp’s input common-mode voltage vs. output voltage range. If the operating conditions fall within the contour, the device should operate properly; otherwise, the output will be invalid due to saturation of internal nodes.

For readers unfamiliar with in-amps, these linear devices amplify the voltage difference between their inputs, independent of the input voltage relative to the supply voltage. The input common-mode voltage, which is the average of the two input voltages, is rejected by the amplifier.

Naturally, operation is restricted to a limited voltage range, which most people would expect to be less than the supplies, so it’s generally not a problem. However, the common-mode voltage does not simply disappear as it enters the circuit. Instead, it’s internally subtracted from the desired signal. This means that the amplified signal and the common-mode voltage must fit within the voltage rails. The mechanism by which the common-mode voltage is subtracted depends on the particular circuit topology, giving the contour a specific shape, which can be an octagon, hexagon, or parallelogram. Diamond plot can be a bit of a misnomer, but these contour plots provide the circuit designer with useful information regarding the proper operating range given the input voltages, desired output swing, reference voltage, and supply rails.

This problem becomes more challenging when working with low supply voltages and single-supply applications, because the diamond plot becomes much smaller and the operation range becomes even more restricted. Modern in-amps such as the AD8226, AD8227, AD8420, and AD8422 aim to expand the diamond plot as much as possible. To simplify low-voltage designs, the AD8237’s diamond plot exceeds the supply, as shown in Figure 1.

So, next time you’re designing with an in-amp, remember to consider the diamond plot. At least this plot won’t get Interpol knocking on your door to recover the stolen rocks!

RAQ:  Issue 107 Figure 1
Figure 1. Input common-mode voltage vs. output voltage.

In the News:

Cline, Seth. The 7 Biggest Diamond Heists in Recent Memory: Multi-million dollar diamond heists aren't reserved to Hollywood. US News. February 19, 2013.

Michaels, Daniel. Arrests Made in Diamond Heist. Diamonds, Bags of Cash Are Recovered in Sweep Across France, Switzerland and Belgium. The Wall Street Journal. May 8, 2013.

Design Tools:

EngineerZone: Help us test our new in-amp tool, and it may help your design...

Instrumentation Amplifier Operating Range Tool


Gustavo Castro

Gustavo Castro

Gustavo Castro is a system applications engineer in the Linear and Precision Technology Group in Wilmington, MA. His main interests are analog and mixed-signal design for precision signal conditioning and electronic instrumentation. Prior to joining Analog Devices in 2011, he worked for 10 years designing high performance digital multimeters and precision dc sources at National Instruments. Gustavo received his B.S. degree in electronic systems from Tecnológico de Monterrey and his M.S. degree in microsystems and materials from Northeastern University. He holds three patents.