Figure 2. An Ultra-Low-Power Op Amp Offers Simple, Positive Polarity Output to Support a Zero
Bias Condition
For a more comprehensive assessment, the circuit in Fig. 3 tests the solar source to see if it can handle the load.
The circuit shown makes this assessment without burdening the microcontroller and risking collapse of the supply
during measurement.
Figure 3. An Ultra-Low-Power Op-Amp-based Circuit Assesses A Pv Solar-Cell Source
Approximately once per 100 ms, the circuit disconnects the solar-cell power source from its reservoir capacitor and
load, applying a test load (R1) and assessing the resulting voltage drop. If the voltage drops 25% or more, the
result is latched into U2 and the power status is provided to the microcontroller.
This ultra-low power circuit draws less than 3 µA at 1 V. Op amp U1 provides the timer function and controls
transistor switches T1 and T2 to apply the test load while simultaneously disconnecting the load. Capacitor C1
temporarily holds the voltage to keep this circuitry and any standby loads powered. Op amp U2 serves as a
comparator, tripping when the power source drops more than 25% (with 5% hysteresis). Transistor T3 latches the
result, while transistor T4 resets the latch during each assessment period to ensure a fresh reading.
Such test loading is useful for determining the available power from a solar cell, since merely measuring the open
circuit voltage generally does not provide an accurate assessment.
2
Rev. 1.0
AN843
2.1. Assessing “Always-On” Circuitry
Generally, an ultra-low-power op amp, like the TS1001, is an excellent option for supporting “always-on” analog
circuitry. For example, op amps that are guaranteed to operate under 1 V and consume less than 1 µA current may
be configured as a filter and left continually on, so that a microcontroller making an ADC measurement does not
have to stay powered on while the filter settles.
In conclusion, ultra-low-power op amps are useful in low-power solar systems to assess the available power from
solar cells before a load is applied, and generally to support standby, “always-on” circuitry, while drawing negligible
currents.
For additional information, see the documentation for the TS1001 or contact Silicon Labs.
Rev. 1.0
3
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using or intending to use the Silicon Laboratories products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific
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