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Design a Logic Probe

Design a Logic Probe. Experiment 20. +9V supply may be replaced with a +5V supply from the ANDY board or a DC voltage from the Velleman function generator. Design Specifications.

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Design a Logic Probe

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  1. Design a Logic Probe Experiment 20

  2. +9V supply may be replaced with a +5V supply from the ANDY board or a DC voltage from the Velleman function generator.

  3. Design Specifications Design a logic probe as shown in the block diagram of Figure 1 with a signal input lead, a ground lead, and a power input lead. The logic probe should have three output LEDs. Only one LED at a time should light when the input is a steady DC level between zero and +5 V. • LED 1 should light when the input voltage is below 0.8 V. • LED 2 should light (a) when the input is open (floating) or (b) when the input voltage is between 0.8 and 2.2 V. • LED 3 should light when the input voltage is above 2.2 V. • All voltage levels have a tolerance of approximately ±12%. Ideally, your design should use only one LM324 chip. You may use all four of the LM324's op amps on the chip. No extra credit will be awarded. You may use either the +5 or +9V ANDY board supply or a DC voltage supplied by the Velleman function generator.

  4. Varying Input Voltage • In addition to the circuit with the voltage comparators, you must design and construct a voltage divider so that you can vary the input voltage to the logic probe during validation using a 100 kW trim pot.

  5. Pre-Lab Report should include: • Explanation of the principles applied in the circuit design. • Schematic diagram of the circuit that you designed using PSpice (i.e., not drawn by hand). • Schematic diagram that show the bias voltages (Procedure Part B, step 6). • Schematics should also include the locations of any PSpice voltage and/or current markers. • PSpice screen snapshots of: • A graph of the input voltage to the logic probe versus the output voltages from the op amps (Procedure Part B, step 7). The graph should cover the entire range of voltages that illustrate all three logic levels (i.e., a DC Sweep). • A graph of logic probe input voltage versus the voltage across the series combination of an LED and its current limiting resistor using at least one PSpice differential voltage probe (Procedure Part B, step 8) or an equivalent trace expression. • A graph of logic probe input voltage versus the current through each of the three LEDs (Procedure Part B, step 9).

  6. Final Report should include: • The material from your pre-lab. • A table of the input voltages that turn on and turn off each LED and a discussion of the hysteresis of these voltages. • If there is significant hysteresis, an explanation on how might you modify your design to eliminate these effects. • A conclusion that states whether you circuit met the design specifications and what some of the causes that contributed to issues with the circuit operation.

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