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Difference between revisions of "TM4C123G LaunchPad - 7 Segment LED Interface"

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(Created page with "== Seven-segment LED interfacing == The 7-seg LED can have '''common anode''' or '''common cathode'''. With common anode, the anode of the LED is driven by the positive supply...")
 
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== Seven-segment LED interfacing ==
 
== Seven-segment LED interfacing ==
 
The 7-seg LED can have '''common anode''' or '''common cathode'''. With common anode, the anode of the LED is driven by the positive supply voltage and the microcontroller drives the individual cathodes '''LOW''' for current to flow through LEDs to light up. In this configuration, the sink current capability of the microcontroller is critical. With common cathode, the cathode of the LED is grounded and microcontroller drives the individual anodes '''HIGH''' to light up the LED. In this configuration, the microcontroller pins must provide sufficient source current for each LED segment. In either configurations, if the microcontroller does not have sufficient drive or sink current capacity, we must add a buffer between the 7-seg LED and the microcontroller. The buffer for the 7-seg LED can be an IC chip or transistors.
 
The 7-seg LED can have '''common anode''' or '''common cathode'''. With common anode, the anode of the LED is driven by the positive supply voltage and the microcontroller drives the individual cathodes '''LOW''' for current to flow through LEDs to light up. In this configuration, the sink current capability of the microcontroller is critical. With common cathode, the cathode of the LED is grounded and microcontroller drives the individual anodes '''HIGH''' to light up the LED. In this configuration, the microcontroller pins must provide sufficient source current for each LED segment. In either configurations, if the microcontroller does not have sufficient drive or sink current capacity, we must add a buffer between the 7-seg LED and the microcontroller. The buffer for the 7-seg LED can be an IC chip or transistors.
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The seven segments of LED are designated as '''a''', '''b''', '''c''', '''d''', '''e''', '''f''', and '''g''' as shown in the following figure:
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[[image:7_segment_led.png|center]]
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A byte of data should be sufficient to drive all of the segments. In the example below, segment '''a''' is assigned to bit '''D0''', segment '''b''' is assigned to bit '''D1''', and so on as shown below:
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{| class="wikitable"
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|-
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| colspan="8"|'''Assignments of port pins to each segments of a 7-seg LED'''
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|-
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| D7 || D6 || D5 || D4 || D3 || D2 || D1 || D0
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|-
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| '''.''' || g || f || e || d || c || b || a
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|}

Revision as of 06:42, 22 January 2018

Seven-segment LED interfacing

The 7-seg LED can have common anode or common cathode. With common anode, the anode of the LED is driven by the positive supply voltage and the microcontroller drives the individual cathodes LOW for current to flow through LEDs to light up. In this configuration, the sink current capability of the microcontroller is critical. With common cathode, the cathode of the LED is grounded and microcontroller drives the individual anodes HIGH to light up the LED. In this configuration, the microcontroller pins must provide sufficient source current for each LED segment. In either configurations, if the microcontroller does not have sufficient drive or sink current capacity, we must add a buffer between the 7-seg LED and the microcontroller. The buffer for the 7-seg LED can be an IC chip or transistors.

The seven segments of LED are designated as a, b, c, d, e, f, and g as shown in the following figure:

7 segment led.png

A byte of data should be sufficient to drive all of the segments. In the example below, segment a is assigned to bit D0, segment b is assigned to bit D1, and so on as shown below:

Assignments of port pins to each segments of a 7-seg LED
D7 D6 D5 D4 D3 D2 D1 D0
. g f e d c b a