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7-Segment Display Multiplexing Control with Parallel Port and x86 Assembly

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15 Aug 2012GPL37 min read 89.7K   5  
Time division multiplexing between 6 x 7-Segment displays control with Parallel Port and x86 assembly.

Introduction

This article is about controlling 7-segment displays in real time via parallel port and x86 assembly. Project contains SN74LS57N decoder/driver, 74HC238 demultiplexer/driver and 6 Seven-segment displays. I will show how to multiplexing between 6 Seven-segment displays with a single decoder/driver.

Image 1

http://youtu.be/kwiHF2zoIpI

The materials needed

  • SN74LS47N BCD to 7-segment display decoder. (for anode displays)
  • 74HC238 3 to 8 demultiplexer
  • 6 x anode 7-Segment display
  • Breadboard
  • About 5 meter cable

1.What is the Multiplexing and Demultiplexing ?

Multiplexing, a source, shared among many users that use it. The multiplexed signal is transmitted over a communication channel, which may be a physical transmission medium. The multiplexing divides the capacity of the high-level communication channel into several low-level logical channels, one for each message signal or data stream to be transferred. A reverse process, known as demultiplexing, can extract the original channels on the receiver side. A device that performs the multiplexing is called a multiplexer (MUX), and a device that performs the reverse process is called a demultiplexer (DEMUX). Inverse multiplexing (IMUX) has the opposite aim as multiplexing, namely to break one data stream into several streams, transfer them simultaneously over several communication channels, and recreate the original data stream. There is 4 type space-division multiplexing (SDM), frequency-division multiplexing (FDM), time-division multiplexing (TDM), and code division multiplexing (CDM).

1.1 What is the Time-Division Multiplexing ?

Time-division multiplexing (TDM) is a type of digital (or rarely analog) multiplexing in which two or more bit streams or signals are transferred apparently simultaneously as sub-channels in one communication channel, but are physically taking turns on the channel.

1.2 Time-Division Multiplexing in this Project

TDM simply we can say sharing the resource each part in equal time.


Image 2
Figure1


Image 3
Figure2

Each line should selected very quickly. If duration of each group 1 sec instead of 1/1000 sec (1 khz) system will show like Figure 3.


Image 4
Figure3

The human brain can not detect this fast switching operation. There is several advantages of this method. Most important advantages is using just single source. In this project I shared SN74LS47N decoder between parallel connected 6 x Seven-Segment displays.

2.Seven-Segment Displays

7-Segment display is kind of binary to decimal converter. There is two types of displays. Common anode and common cathode.

Image 5

Main difference between common anode and common cathode 7-segment.

Image 6

Truth Table of 7-Segment Displays

3.SN74LS47N BCD to Seven-Segmen Decoder/Driver

SN74LS47N Decoder/Driver uses for anode displays. There is 4 bit bcd input and 7 display output. The SN74LS47 are Low Power Schottky BCD to 7-Segment Decoder/Drivers consisting of NAND gates, input buffers and seven AND-OR-INVERT gates. They offer active LOW, high sink current outputs for driving indicators directly. Seven NAND gates and one driver are connected in pairs to make BCD data and its complement available to the seven decoding AND-OR-INVERT gates. The remaining NAND gate and three input buffers provide lamp test, blanking input / ripple-blanking output and ripple-blanking input. The circuits accept 4-bit binary-coded decimal (BCD) and, depending on the state of the auxiliary inputs, decodes this data to drive a 7-segment display indicator. The relative positive-logic output levels, as well as conditions required at the auxiliary inputs, are shown in the truth tables. Output configurations of the SN74LS47 are designed to withstand the relatively high voltage required for 7-segment indicators. These outputs will withstand 15 V with a maximum reverse current of 250 mA. Indicator segments requiring up to 24 mA of current may be driven directly from the SN74LS47 high performance output transistors. Display patterns for BCD input counts above nine are unique symbols to authenticate input conditions.

Image 7
Pin Diagram of SN74LS47N

Image 8

Pin Description of SN74LS47N

Image 9
Truth Table of SN74LS47N

4. 74HC238 3 to 8 line Decoder/Demultiplexer

The 74HC/HCT238 are high-speed Si-gate CMOS devices and are pin compatible with low power Schottky TTL (LSTTL). They are specified in compliance with JEDEC standard no. 7A. The 74HC/HCT238 decoders accept three binary weighted address inputs (A0, A1, A2) and when enabled, provide 8 mutually exclusive active HIGH outputs (Y0 to Y7). The “238” features three enable inputs: two active LOW (E1 and E2) and one active HIGH (E3). Every output will be LOW unless E1 and E2 are LOW and E3 is HIGH. This multiple enable function allows easy parallel expansion of the “238” to a 1-of-32 (5 lines to 32 lines) decoder with just four “238” ICs and one inverter. The “238” can be used as an eight output demultiplexer by using one of the active LOW enable inputs as the data input and the remaining enable inputs as strobes. Unused enable inputs must be permanently tied to their appropriate active HIGH or LOW state. The “238” is identical to the “138” but has non-inverting outputs.

Image 10

Pin Diagram of 74HC238

Image 11
Pin Description of 74HC238

Image 12
Truth Table of 74HC238

5.Parallel Port (LPT Port)

Parallel pots are personal computer interfaces that transfer data (generally) a byte at a time. Parallel ports conform to the specifications of a document of the Institute of Electrical and Electronic Engineers (IEEE) called IEEE Std 1284-1994: Standard Signaling. Method for a Bi-directional Parallel Peripheral Interface for Personal Computers, or IEEE 1284 for short. Basically, IEEE-1284 gathers and harmonizes standards for parallel transmission that were already in use. It describes a system of asynchronous, fully interlocked, bi-directional communications between a peripheral (often a printer) and host (usually a PC).

Image 13

The IEEE 1284 parallel port modes are called

Compatibility mode,
Nibble mode,
Byte mode,
Enhanced mode,
Enhanced Parallel Port (EPP),
Extended Cağabilities Port (ECP)

Image 14
Pin Diagram of Parallel Port

Image 15
Pin Description of Parallel Port

Image 16
Standart Parallel Port Addresses

IEEE 1284 level II

Data output (>2.4V) 14 mA

Data line sink (<0.4V) 14 mA

Control output (>2.4 V) ?

Signal lines (short circuit) ?

Control line sink (<0.4V) 14 mA

6.Designing Circuit

Basic part of the project design the circuit. I decided to use just 8 data register from LPT port.

Image 17

All seven segment displays are connected parallel each other. First 4 bit (pin 2 to 5) from parallel port reserved for SN74LS47N data inputs. This means shown digit is determined here. Next 3 bit (pin 6 to 8) from parallel port reserved for 74HC238 switching input. Last bit (pin 9) used for Vcc inputs of the system.

Decimal 128-255

D7 Vcc

D6,D5,D4 74238 BCD

D3,D2,D1,D0 7447 BCD

Selected Display

Displayed Number

129

1

000

0001

1

1

144

1

001

0000

2

0

160

1

010

0000

3

0

176

1

011

0000

4

0

192

1

100

0000

5

0

208

1

101

0000

6

0

130

1

000

0010

1

2

144

1

001

0000

2

0

160

1

010

0000

3

0

176

1

011

0000

4

0

192

1

100

0000

5

0

208

1

101

0000

6

0

Some Part of System's Truth Table

SEG1 SEG2 SEG3 SEG4 SEG5 SEG6
128 0 144 0 160 0 176 0 192 0 208 0
129 1 145 1 161 1 177 1 193 1 209 1
130 2 146 2 162 2 178 2 194 2 210 2
131 3 147 3 163 3 179 3 195 3 211 3
132 4 148 4 164 4 180 4 196 4 212 4
133 5 149 5 165 5 181 5 197 5 213 5
134 6 150 6 166 6 182 6 198 6 214 6
135 7 151 7 167 7 183 7 199 7 215 7
136 8 152 8 168 8 184 8 200 8 216 8
137 9 153 9 169 9 185 9 201 9 217 9
+7 Don’t Care

7. How to Programming in x86 Assembly ?

ASM
mov cx,0ffffh 
loop1:
mov dx,03bch
MOV al,10000000b
out dx,al
dec cx
jnz loop1

This code block send the (128d) 10000000b logic high and low voltage respectively d7,d6,d5,d4,d3,d2,d1,d0 pins and loop show digit during about 1 second 800Mhz processor high priority on windows xp operating system. During time exactly can’t calculated for different systems. Refresh rate and streaming rate will never be able to stable on different machines. Modern Real time operating systems shares the resources with many threats. if I used the pick controller on this project it can be calculated exacly.

ASM
MOV bl,127d

mov cx,10d ; loop1 count last digit 0 to 9
next:
push cx

INC bl


mov cx,5d ; loop2 scan 5 times
duration:
push cx ; LIFO


mov cx,0500h ; loop3 duration of digit
loop1:
mov dx,03bch
MOV al,bl
out dx,al
dec cx
jnz loop1

mov cx,0500h
loop2:
mov dx,03bch
MOV al,144d
out dx,al
dec cx
jnz loop2

mov cx,0500h
loop3:
mov dx,03bch
MOV al,160d
out dx,al
dec cx
jnz loop3

mov cx,0500h
loop4:
mov dx,03bch
MOV al,176d
out dx,al
dec cx
jnz loop4

mov cx,0500h
loop5:
mov dx,03bch
MOV al,192d
out dx,al
dec cx
jnz loop5

mov cx,0500h
loop6:
mov dx,03bch
MOV al,208d
out dx,al
dec cx
jnz loop6


pop cx ; loop2
loop duration

pop cx ; loop3
loop next

8. References

  1. SN74LS47N semiconductor datasheet
  2. 74HC238 philips datasheet
  3. IEEE 1284 STD

9. Contact

http://blog.armanasci.com

License

This article, along with any associated source code and files, is licensed under The GNU General Public License (GPLv3)


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