Adding a biasing network to A1 allows its output to be at 0 mV (common) when sensing 0 °C, and to swing negative for lower temperatures
| Authors | Nick Cornford |
| Main Document | Article «Newer, shinier DMM RTDs. Part 2» |
| Description | Figure 2 |
| File Format / Size | PDF / 24 Kb |
| Document Language | English |
Other Materials from the Main Document
- Article «Newer, shinier DMM RTDs. Part 2»
- Figure 1. Using a precision op-amp lets us set the output reference level with a passive network because thermal drifts and mismatches are no longer a problem. LED1 acts both as a rail-splitter and a power indicator, while LED2 gives a simple low-battery warning. T
- Figure 2. Adding a biasing network to A1 allows its output to be at 0 mV (common) when sensing 0 °C, and to swing negative for lower temperatures
- Figure 3. Plotting the errors for various values of R5 - the positive feedback resistor - shows that we can optimize performance for minimal errors around 0-100 °C (magenta) or accept a wider error band over a greater temperature range. The red curve is within
- Figure 4. Changing three components gives an output of 1 mV/°Fahrenheit
- Figure 5. A small negative offset allows the basic circuit to give an output directly proportional to absolute temperature
- Figure 6. Stripping out all the frills and fancies leaves a basic circuit that is ideal for running off split rails and compatible with most ADCs
- Figure 7. Referring the output from the amplifying stage to either a positive reference or to common allows the indication to be switched between Celsius and Kelvin