Schematic Symbol for PIC16F887-I/P: PIC series Microcontroller IC...

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Design a timer circuit using PIC16F887, with reset, stop, and start buttons

bichvan

@copilot Design a timer circuit using PIC16F887, with reset, stop, and start buttons

copilot

To design a timer circuit using the PIC16F887 that includes reset, stop, and start buttons, you will need to consider both the hardware connections and the software programming for this microcontroller. Since we're focusing on the hardware design here, I will outline how to connect the buttons and suggest a basic approach for the software.

Assumptions:

Reset, Stop, and Start Buttons: Normally open pushbuttons are used.
I/O Pins: Using digital I/O pins for button inputs. Pins can be configured as input with internal pull-up resistors enabled in software to simplify circuitry.
External Components: Minimal external components assumption (debouncing for buttons handled in software).

Hardware Connections: Power Connections:

Connect VDD pins to a +5V power supply.
- Connect VDD:P11 and VDD:P32 to +5V.
Connect VSS pins to ground.
- Connect VSS:P12 and VSS:P31 to GND.

Button Connections:

Reset Button (Assigned to MCLR for hardware reset feature):
- Connect one side of the Reset button to RE3/MCLR/Vpp:P1.
- Connect the other side to +5V.
- Note: This pin is an active-low reset, so pulling it to VDD disables the reset. Pressing the button applies +5V directly, which normally wouldn't trigger a reset unless an external pull-down resistor is used to keep the pin normally at GND. Alternatively, this button could be connected to GND, and an external pull-up resistor used if software-controlled reset is not desired.
Stop Button (Using a general-purpose I/O):
- Connect one side of the Stop button to RD0:P19 (or another free digital I/O pin).
- Connect the other side to GND.
- Enable internal pull-up resistor for RD0 in software.
Start Button (Using a different general-purpose I/O to differentiate from stop):
- Connect one side of the Start button to RD1:P20 (or another designated I/O pin).
- Connect the other side to GND.
- Enable internal pull-up resistor for RD1 in software.

Optional:

To use an LED or another indicator for timer status, connect the LED with a series resistor to a designated digital I/O pin and the other side to GND. Ensure the pin used is set as an output in your code.

Sample Connections Summary:

Connect VDD:P11 and VDD:P32 to +5V.
Connect VSS:P12 and VSS:P31 to GND.
Connect Reset button to RE3/MCLR/Vpp:P1 and the other side to +5V.
Connect Stop button to RD0:P19 and GND.
Connect Start button to RD1:P20 and GND.

Software Outline:

Initialize the PIC16F887 I/O pins for the buttons and any output indicators (e.g., LEDs).
Poll the input pins connected to the Start and Stop buttons in your main loop, debouncing each button in software.
Implement an interrupt service routine that increments a counter every timer tick when the timer is active. This will be your timer's base.
Control the timer with Start and Stop buttons: start the timer counting on a Start button press, and stop it on a Stop button press.
Reset Feature: Implement a feature that resets the counter to 0 on a Reset button press. This might be done with an external interrupt or polling, depending on how you've set up the Reset button. If connected directly to MCLR, the reset functionality will be inherent but will restart the entire program, not just the counter.

Remember, the bulk of the timer functionality—such as counting time, debouncing button inputs, and responding to button presses—will be managed in the software you program into the PIC16F887. Ensure your code is robustly designed to handle these tasks efficiently.

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