Analog Clock Motor Driver

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Analog Clock Motor Driver

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Even in a digital world, classic analog clocks have a timeless style that is here to stay. We can use a dual-rail GreenPAK™ CMIC to implement all the active electronic functions needed in an analog clock, including motor driver and crystal oscillator. GreenPAKs are low-cost, tiny devices that fit right in with smart watches. As an easy-to-build demonstration, I obtained a cheap wall clock, removed the existing board, and replaced all the active electronics with one GreenPAK device.

You can go through all steps to understand how the GreenPAK chip has been programmed to control Analog Clock Motor Driver. However, if you just want to easily create the Analog Clock Motor Driver without having to go through all the inner circuitry, download GreenPAK software to view the already completed Analog Clock Motor Driver GreenPAK Design File. Plug the GreenPAK Development Kit to your computer and hit "program" to create the custom IC to control your Analog Clock Motor Driver. The next step will discuss the logic that is inside the Analog Clock Motor Driver GreenPAK design file for those that are interested in understanding how the circuit works.

Background: Lavet Type Stepper Motors

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A typical analog clock uses a Lavet type stepper motor to turn the pinion gear of the clock mechanism. It is a single-phase motor that consists of a flat stator (stationary part of the motor) with an inductive coil wrapped around an arm. Between the arms of the stator lies the rotor (moving part of the motor) which consists of a circular permanent magnet with a pinion gear attached to the top of it. The pinion gear coupled with other gears move the clock hands. The motor works by alternating the polarity of current in the stator coil with a pause between the polarity changes. During current pulses, the induced magnetism pulls the motor to align the poles of the rotor and stator. While the current is off, the motor is pulled to one of two other positions by reluctant force. These reluctance rest positions are engineered by the design of non-uniformities (notches) in the metal motor housing so that the motor rotates in one direction (see Figure 1).

Motor Driver

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The attached design uses a SLG46121V to produce the required current waveforms though the stator coil. Separate 2x push-pull outputs on the IC (labeled M1 and M2) connect to each end of the coil, and drive the alternating pulses. It is necessary to use push-pull outputs for this device to operate correctly. The waveform consists of a 10 ms pulse each second, alternating between M1 and M2 with each pulse. The pulses are created with just a few blocks driven from a simple 32.768 kHz crystal oscillator circuit. The OSC block conveniently has built in dividers to help divide down the 32.768 kHz clock. CNT1 outputs a clock pulse every second. This pulse triggers a 10 ms one-shot circuit. Two LUTs (labeled 1 and 2) demultiplex the 10 ms pulse to the output pins. Pulses are passed to M1 when DFF5 output is high, M2 when low.

Crystal Oscillator

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The 32.768 kHz crystal oscillator uses just two pin blocks on the chip. PIN12 (OSC_IN) is set as a low-voltage digital input (LVDI), which has relatively low switching current. The signal from PIN12 feeds into the OE of PIN10 (FEEDBACK_OUT). PIN10 is configured as a 3-state output with input wired to ground, making it act like an open drain NMOS output. This signal path naturally inverts, so no other block is needed. Externally, the PIN 10 output is pulled up to VDD2 (PIN11) by a 1MΩ resistor (R4). Both PIN10 and PIN12 are powered by the VDD2 rail, which in-turn is current limited 1 MΩ resistor to VDD. R1 is a feedback resistor to bias the inverting circuit, and R2 limits output drive. Adding the crystal and capacitors completes the Pierce oscillator circuit as shown in Figure 3.

Results

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VDD was powered by a CR2032 lithium coin battery which typically provides 3.0 V (3.3 V when fresh). The output waveform consists of alternating 10 ms pulses as shown below in Figure 4. Averaged over a minute, the measured current draw was roughly 97 uA including the motor drive. Without the motor, the current draw was 2.25 µA.

Conclusion

This application note provides a GreenPAK demonstration of a complete solution for driving an analog clock stepper motor and can be the basis for other more specialized solutions. This solution only uses a portion of the GreenPAK resources, which leaves the IC open to additional functions left only to your imagination.