AD8495 Interface to Type T Thermocouples

Thermocouples are a common, inexpensive way to make precision temperature measurements over wide temperature ranges. Type T thermocouples (copper constantan) are sensitive, stable, easy to manufacture, and moisture tolerant—and the copper-to-copper connection to the printed circuit board eliminates the need for an isothermal block. These are some of the main reasons that type T thermocouples are chosen for many applications, from catheters to food processing, that don’t need the full temperature range available from other thermocouples such as type K.

ADI makes thermocouple amplifiers with built-in cold-junction compensation, but not for type T thermocouples. Fortunately, type T and type K amplifiers have similar voltage characteristics up to about 100°C. Type K thermocouple conditioners such as AD8495 or AD8497 can take advantage of this similarity to measure type T thermocouples with very low errors. The output voltage for higher temperatures will deviate from the ideal 5 mV/°C transfer function of the AD8495, so it is necessary to account for the difference with a lookup table or polynomial. The figure was generated using the type T thermocouple table from NIST and the transfer function of the AD8495 in order to show the AD8495 output at various reference junction temperatures.

Figure 1. AD8495 calculated output with type T thermocouple.

The graph or this 6th order polynomial can be used to map the output voltage to the measurement temperature. VOUT (mV) = a0 + a1 × T + a2 × T2 + … + a6 × T6, where the coefficients are:

a6 a5 a4 a3 a2 a1 a0
 2.115 × 10–16 –2.116 × 10–12 2.602 × 10–9 –4.238 × 10–6  5.548 × 10–3 4.728 1.099

Over the full –200°C to +350°C measurement temperature range and 0°C to 50°C reference junction temperature range, the calculated error of this polynomial is approximately –2.50 mV to +2.28 mV, which is less than about ±0.5°C. Thermocouple tolerance and AD8495 amplifier errors must be added.

Notice that the output voltage is negative for temperatures below 0°C. The output voltage is measured with respect to the reference pin (REF), so the voltage at REF can be raised to accommodate the negative output voltage with a single supply. See the AD8495 data sheet for important considerations when designing with thermocouples, including grounding, filtering interference, and layout practices in order to keep the device temperature equal to the reference junction temperature.


Scott Hunt

Scott Hunt

Scott Hunt is a system applications engineer specializing in scientific instruments in the Instrumentation Market Group of Analog Devices in Wilmington, MA. Scott joined Analog Devices in 2011 as a product applications engineer for high performance integrated precision amplifiers, such as instrumentation amplifiers, before transferring into the instrumentation group in 2016. He has a bachelor’s degree in electrical and computer systems engineering from Rensselaer Polytechnic Institute. Scott was honored as a recipient of the 2015 Outstanding Technical Writing award and the 2015 Outstanding Program Support award from Analog Devices.