Designers often have questions about a typical specification of an amplifier to design a more robust circuit. Due to natural variation in process technology and manufacturing procedures, every specification of an amplifier exhibits some amount of deviation from the ideal value, like an amplifier's input offset voltage. These deviations often follow Gaussian (bell curve), or normal distributions, and circuit designers can leverage this information to guardband their system, even when there is not a minimum or maximum specification in Section 6.7.

Figure 7-11 Ideal Gaussian Distribution

Figure 7-11 shows an example distribution, where µ, or mu, is the mean of the distribution, and where σ, or sigma, is the standard deviation of a system. For a specification that exhibits this kind of distribution, approximately two-thirds (68.26%) of all units can be expected to have a value within one standard deviation, or one sigma, of the mean (from µ–σ to µ+σ).

Depending on the specification, values listed in the typical column of the Section 6.7 table are represented in different ways. As a general rule, if a specification naturally has a nonzero mean (for example, like gain bandwidth), then the typical value is equal to the mean (µ). However, if a specification naturally has a mean near zero (like input offset voltage), then the typical value is equal to the mean plus one standard deviation (µ + σ) to most accurately represent the typical value.

This chart can be used to calculate approximate probability of a specification in a unit; for example, for OPAx992-Q1, the typical input voltage offset is 210 µV. So 68.2% of all OPAx992-Q1 devices are expected to have an offset from –210 µV to +210 µV. At 4 σ (±840 µV), 99.9937% of the distribution has an offset voltage less than ±840 µV, which means 0.0063% of the population is outside of these limits, which corresponds to about 1 in 15,873 units.

Specifications with a value in the minimum or maximum column are specified by TI, and units outside these limits are removed from production material. For example, the OPAx992-Q1 family has a maximum offset voltage of 1 mV at 25°C, and even though this corresponds to slightly less than 5 σ (≅1 in 1.7 million units), which is extremely unlikely, TI maintains that any unit with larger offset than 1 mV is removed from production material.

For specifications with no value in the minimum or maximum column, consider selecting a sigma value of sufficient guardband for the application, and design worst-case conditions using this value. For example, the 6-σ value corresponds to about 1 in 500 million units, which is an extremely unlikely chance, and can be an option as a wide guardband to design a system around. In this case, the OPAx992-Q1 family does not have a maximum or minimum for offset voltage drift. But based on the typical value of 0.25 µV/°C in the Section 6.7 table, the 6-σ value for offset voltage drift is about 1.5 µV/°C when calculated. When designing for worst-case system conditions, this value can be used to estimate the worst possible offset across temperature without having an actual minimum or maximum value.

Note that process variation and adjustments over time can shift typical means and standard deviations, and unless there is a value in the minimum or maximum specification column, TI cannot verify the performance of a device. This information must be used only to estimate the performance of a device.