SCDA061 February 2025 CD4053B , CD74HC4066 , SN74LVC1G3157 , SN74LVC1G66 , TMUX1219 , TMUX4053 , TS5A3166 , TS5A3167
To achieve cost-effective sensor data processing, system designers often use a bidirectional analog multiplexer with operational amplifiers (op-amps) to create an input interface. This combination allows one multiplexer to connect to multiple downstream signal paths, each with different gain configurations for the op-amps. This combination enhances data transmission efficiency and functionality from a single sensor.
A problem can occur when the input resistance of an op-amp, such as the TLV9004, is significantly greater than the off resistance of a multiplexer. If these compatibility issues are not considered during system design, voltage errors can arise on the multiplexer's unselected signal path. This can lead to incorrect voltage readings being transmitted downstream to various data processing devices, resulting in measurement errors in the application.
To prevent voltage errors that may arise on the unselected signal path in this application, designers can implement a bleeder switch in combination with a pulldown resistor placed parallel to the operational amplifier (op-amp). This approach is effective because when the bleeder switch is closed, the pulldown resistor becomes parallel to the input resistance of the op-amp. This arrangement alters the resistance ratio between the off-resistance of the multiplexer and the op-amp load resistance. As a result, the off-resistance is greater than the load resistance, allowing more voltage to drop across the multiplexer. This reduces the voltage at the op-amp's input, effectively discharging the floating node or high impedance of the op-amp input. Ultimately, if a strong pulldown resistor is used, the voltage seen by the op-amp's input on the unselected signal path can be approximately 0V.
To implement this solution, the bleeder switch must connect when the signal path is unselected and disconnect when it is selected. This allows the system to transmit the correct voltage reading from the sensor to the op-amp through the selected multiplexer signal path. Figure 2 and Figure 3 show the implementation of the bleeder switch solution, while Figure 4 shows a system implementation of this solution. Furthermore, system designers can alternatively use a bleeder multiplexer to connect pulldown resistors in their application. Figure 5 illustrates how a multiplexer can be used to connect and disconnect multiple pulldown resistors.
To help designers understand the relationship between a multiplexer’s off resistance and an op amp’s input resistance, as well as to estimate the necessary bleeder resistor for their application, they should start by determining an acceptable voltage level for the op amp’s input when the multiplexer signal path is unselected.
Once this voltage level is established, they can use the multiplexer’s maximum off-leakage current along with the acceptable voltage level of the unselected signal path to estimate the required bleeder resistor.
For example, if the acceptable voltage on the unselected signal path is 0.2V and the maximum off-leakage current of the multiplexer is 1000nA, then by rearranging Ohm's Law (V/I = R), we can find that the bleeder resistor needs to be less than 200 kilohms.
Part Number | Supply Range (V) | Configuration | Channel Count | Control Logic |
---|---|---|---|---|
TS5A3166 | 1.65 to 5.5V | 1:1(SPST) Switch | 1 | Active High |
SN74LVC1G66 | 1.65 to 5.5V | 1:1(SPST) Switch | 1 | Active High |
CD74HC4066 | 2 to 10V | 1:1(SPST) Switch | 4 | Active High |
TS5A3167 | 1.65 to 5.5V | 1:1(SPST) Switch | 1 | Active Low |
TMUX1219 | 1.08 to 5.5V | 2:1(SPDT) Multiplexer | 1 | Active High and Low |
SN74LVC1G3157 | 1.65 to 5.5V | 2:1(SPDT) Multiplexer | 1 | Active High and Low |
TMUX4053 | 5 to 24V | 2:1(SPDT) Multiplexer | 3 | Active High and Low |
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