Difference between revisions of "Controlling a seven segment display"

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[[image:CircuitDiag.jpg|thumb|300px|[[Circuit diagram for the 7-segment display circuit]]|right]]
[[image:CircuitDiag.jpg|thumb|300px|[[Circuit diagram for the 7-segment display circuit]]|right]]

[[image:7SegmentCircuit3.jpg|thumb|300px|[[Close-up picture of circuit wiring]]|left]]


For the simplest of cases (which is what this module will demonstrate), the decoder needs to receive the number to be displayed in 4-bit binary form. In addition, the 7-segment display will need the seven independent segment outputs from the decoder as well as one decimal point input and one digit select input for each digit being used (all others can be set to ground to ensure they are not active). In the simplest case (displaying one digit only) the PIC need not have an output to control which digit is active. For more complex displays which have multiple digits, up to three digits could reasonably be controlled by the PIC directly, or a decoder could be used for four or more digits so that the PIC need only output the binary number of the desired digit and the decoder would activate the appropriate digit on the display.
For the simplest of cases (which is what this module will demonstrate), the decoder needs to receive the number to be displayed in 4-bit binary form. In addition, the 7-segment display will need the seven independent segment outputs from the decoder as well as one decimal point input and one digit select input for each digit being used (all others can be set to ground to ensure they are not active). In the simplest case (displaying one digit only) the PIC need not have an output to control which digit is active. For more complex displays which have multiple digits, up to three digits could reasonably be controlled by the PIC directly, or a decoder could be used for four or more digits so that the PIC need only output the binary number of the desired digit and the decoder would activate the appropriate digit on the display.
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[[image:7SegmentCircuit3.jpg|thumb|300px|[[Close-up picture of circuit wiring]]|right]]


[[image:LTD4708JS_PinDiag.jpg|thumb|300px|[[Pin diagram for the LTD 4708JS 7-Segment Display]]|left]]
[[image:LTD4708JS_PinDiag.jpg|thumb|300px|[[Pin diagram for the LTD 4708JS 7-Segment Display]]|left]]

Revision as of 15:02, 5 February 2008

Original Assignment

In this project you will use your PIC to display numbers on a seven-segment display.

Overview

In this example, we will be using PIC 18F4520 to control a double digit 7-segment display LTD-4708JS. A few notes about using this display is that it is only designed to display one unit at a time, so when trying to use both digits, you have to use an ISR to switch between the two digits fast enough to create the illusion that both are on simultaneously.

Now, since there are 7 segments, one would assume that you would need 7 outputs from the PIC to display 1 digit. But it is very wasteful to use outputs from the PIC for just displaying, so we will be using a chip (HEF 4543B) that will take 4-bits and convert it to the 7-bit output for the 7-segment display.

If you want to display a decimal, this particular 7-segment display will allow you to do so. However, it will take up another output from your PIC.

Finally, if you are planning on displaying more than one digit, you will need an extra bit for every digit that you want to display.

This Example

The example that you will see here will simply display one digit on the 7-segment display. We will use the PIC to output a value between 0 and 9 using output pins D0-D3. The 4-bits will then be passed to the HEF 4543B chip which will convert it into 7-bits that will control the display. We did not use the decimal point in our example and we only used one of the digits, so we've hard wired the pins that control them to +5V or ground where appropriate.

Capabilities

To display a 2-digit number where a decimal point is needed, you will need a total of 7 outputs from the PIC. 4 for the value, 1 for the decimal point, 2 for each of the digits. However, since you will only be displaying 1 of the 2 digits at any given moment, you can use a logic inverter gate to reduce 1 output needed for selecting which digit to display. Finally, you will need to use an ISR on the PIC with an interval of 5ms to switch between the digits.

Circuit

There are three primary elements required for a circuit involving a 7-segment display.

The elements are:

1) the 7-segment display

2) the controller (in this case the PIC)

3) the decoder

The 7-segment display used in this demonstration was the LTD-4708JS which can display 2 digits with trailing decimal points. The controller was the PIC 18F4520. The decoder used was the HEF 4543B which takes one 4-bit binary input and converts it to the appropriate 7 logic outputs to drive the 7-segment display.


7-Segment Display

The LTD-4708JS 7-segment display has 10 pins. Seven pins correspond to the seven LED segments, one pin corresponds to the decimal point, and two pins select which digit is being activated. Both digits can be activated simultaneously, however they would not be able to display indepent digits in such a manner. To achieve multi-digit display, the digits must alternate back and forth at a rate preferably greater than 45 Hz for a complete cycle of display (approximately the flicker fusion frequency for the human eye, allowing it to appear that all displayed digits are on continuously).

The LTD-4708JS has 10 pins and they are designated as follows:

Pin 1: Segment "C"

Pin 2: Decimal Point

Pin 3: Segment "E"

Pin 4: Select pin for the second digit

Pin 5: Segment "D"

Pin 6: Segment "F"

Pin 7: Segment "G"

Pin 8: Segment "B"

Pin 9: Select pin for the first digit

Pin 10: Segment "A"

note to self: I need to revise the image with labels to the segments and show the order of pins.


Controller

The controller used in this demonstration was the PIC 18F4520. The demonstration outputs were the digital output pins D0-D3 representing the output number in binary form. The PIC was not used to control which digit was used by the display (the display was hardwired instead to display only one digit). For a multiple-digit display a multiplexer could be used to decode a binary output from the PIC specifying the desired active display digit while the PIC outputs the appropriate digit on the data pins, although there is an upper limit to the number of digits which can be output while retaining a display frequency of greater than 45 Hz which is dependent on the time between calls of the ISR used to display a digit. At 50 Hz each digit must be displayed every 20ms, so if the ISR is called every 4ms, then at most 5 digits may be displayed.

Decoder

The decoder used in this demonstration was the HEF 4543B. It receives a 4-bit binary input as an input and outputs seven logic pins which correspond to the respective segments of a 7-segment display unit. Some display units require that the inputs be logic low to set a segment active. To achieve this, the chip has a phase input pin which will invert the outputs when the pin is set high. There is also a Blanking pin which will inhibit outputs, ensuring a blank display when set high. For more information regarding this pin, click on the chip name to access the data sheet or Click Here.

Circuit Wiring

For the simplest of cases (which is what this module will demonstrate), the decoder needs to receive the number to be displayed in 4-bit binary form. In addition, the 7-segment display will need the seven independent segment outputs from the decoder as well as one decimal point input and one digit select input for each digit being used (all others can be set to ground to ensure they are not active). In the simplest case (displaying one digit only) the PIC need not have an output to control which digit is active. For more complex displays which have multiple digits, up to three digits could reasonably be controlled by the PIC directly, or a decoder could be used for four or more digits so that the PIC need only output the binary number of the desired digit and the decoder would activate the appropriate digit on the display.

The yellow wires in the circuit are the four digital output bits from the PIC. In order from LSB to MSB they connect to pins 5, 3, 2 and 4 of the HEF 4543B. If this wiring is not correct, cycling through the numbers from 0-9 will show numbers out of sequence and even missing numbers (binary numbers higher than nine have no output from the decoder).





More to come . . .

Code