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Transcript
2.1.2 RS485 Data Interface
RS485 AC, DC, & PIN power
RS485 Fiber & Copper Modem
RS485 Telephone modems
RS485 converter
RS485 opto isolation
RS485 drivers
RS485 Data Acquisition Communications
Circuit Diagram of Isolated RS485 Interface
Figure 1 shows the circuit diagram of RS485 interface. Connector K1 is
linked to the serial port of the PC, power to the PC side of the circuit is
derived from the signal lines DTR and RTS. Positive supply is derived
from RTS and negative supply from the DTR line. The RTS line is also
used to control the data direction of RS485 driver IC U4.
Optical isolation is achieved by optocouplers U1, U2 and U3. Opto U1 is
used to control the data direction of U4 opto U2 provide RXD line
isolation while opto U3 provide TXD line isolation.
The other side of the isolator carries TTL levels. This side is powered by
an unregulated dc supply between 9V and 18V dc. IC U5 provide 5V
regulated output and IC U4 provide the RS485 bus interface. The TXD
and RXD lines status are provided by data indicating LEDs. The
interface has been tested at the baud rate of 19.2k baud.
For Data Reception
RTS = 1 (at +ve level)
For Data Transmition
RTS = 0 (at -ve level)
DTR line is always set to 0 (at -ve level)
Component details of the project.
1
4 C1,C2,C3,C6
100nF
2
1 C4
10uF 16V
3
1 C5
470uF 25V
4
3 D1,D2,D3
1N4148
5
2 D4,D5
LED RED 3mm
6
2 D7,D6
TRANSIL 6.8V
7
1 D8
1N4003
8
1 K1
DB9 R/A PCB PLUG
9
1 K2
PCB TERMINAL BLOCK 4 WAY
10
3 R1,R2,R3
1K8
11
2 R7,R4
4K7
12
2 R5,R8
1K
13
3 R9,R12
150R
14
1 R6
680R
15
2 R11,R10
10R
16
1 R13
120R
17
2 U3,U1
H11L1 OPTO-ISOLATOR
18
1 U2
CNY17-3 OPTO-ISOLATOR
19
1 U4
MAX487, SN75176B
20
1 U5
LM7805
SELECTION OF TRANSMISSION LINE
FOR RS-485
When choosing a transmission line for RS-485, it is
necessary to examine the required distance of the cable and
the data rate of the system. Losses in a transmission line
are a combination of
•ac losses (skin effect),
• dc conductor loss,
• leakage and
• ac losses in the dielectric.
In high quality cable, the conductor losses and the
dielectric losses are on the same order of magnitude.
CABLE SELECTION FOR RS-422 AND RS-485 SYSTEMS
Selecting data cable for an RS-422 or RS-485 system isn't difficult, but often
gets lost in the shuffle of larger system issues. Care should be taken,
however, because intermittent problems caused by marginal cable can be
very difficult to troubleshoot. Beyond the obvious traits such as number of
conductors and wire gauge, cable specifications include a handful of less
intuitive terms.
Characteristic Impedance (Ohms):
A value based on the inherent conductance, resistance, capacitance and
inductance of a cable that represents the impedance of an infinitely long
cable. When the cable is cut to any length and terminated with this
Characteristic Impedance, measurements of the cable will be identical to
values obtained from the infinite length cable. That is to say that the
termination of the cable with this impedance gives the cable the appearance
of being infinite length, allowing no reflections of the transmitted signal. If
termination is required in a system, the termination impedance value should
match the Characteristic Impedance of the cable.
Shunt Capacitance (pFft):
The amount of equivalent capacitive load of the cable,
typically listed in a per foot basis. One of the factors limiting
total cable length is the capacitive load. Systems with long
lengths benefit from using low capacitance cable.
Propagation velocity (% of c):
The speed at which an electrical signal travels in the cable.
The value given typically must be multiplied by the speed of
light (c) to obtain units of meters per second. For example, a
cable that lists a propagation velocity of 78% gives a velocity
of 0.78 X 300 X 10' - 234 X 106 meters per second.
Transmission Lines

Lumped Element Model

A transmission line or stripline can be formed by
parallel trace pairs (a single trace over a ground
plane), or a coaxial cable. Each of these types of
transmission lines behaves according to the same
equations. For example, one of the key parameters
of a transmission line is its characteristic impedance,
defined as follows:
Zo 

L
C

Where:
 Zo
= characteristic impedance
transmission line
 Ll = trace inductance per unit length
 Cl = trace capacitance per unit length
of
the
Transmission Lines

Lumped Element Model

Signals injected into a transmission line travel down
the line at a speed determined by the inductance
and capacitance per unit length. The equation for
the signal velocity is:
vsignal 

1
LC 
Meters per second
The total time it takes a signal to travel down a
transmission line is therefore equal to the length of
the line divided by the signal velocity. This time is
commonly called the transmission line’s propagation
delay:
Td 
lline
 lline LC seconds
vsignal
Transmission Lines

Lumped Element Model

The wavelength of a sine wave travelling down a
transmission line is given by the equation:
signal 

vsignal
Fsignal
Meters / cycle
The period of the signal should be at least 10 times
larger than the transmission line’s propagation delay
before we can treat the parasitic elements as lumped
rather than distributed.
Transmission Lines

Transmission Line Termination

To understand the purpose of transmission line
termination, let us first examine the behavior of an
unterminated line. An unterminated transmission
line behaves as a sort of electronic echo chamber. If
we transmit a stepped voltage down an
unterminated transmission line, it will bounce back
and forth between the ends of the line until parasitic
resistance in the line eventually causes the echoes to
die out. The resulting reflections appear as
undesirable ringing on the stepped signal. Properly
chosen termination resistors placed at either the
source side or the load side of a transmission line
cause it to behave in a much simpler manner than it
would behave without termination. The purpose of
termination resistors is to dissipate the energy in the
transmitted signal so that reflections do not occur.
Transmission Lines

Transmission Line Termination

If the termination resistor RT is equal to the
characteristic impedance of the transmission line, then
the transmitted signal will not reflect at all. The energy
associated with the currents and voltages propagating
along the transmission line is completely dissipated by
the termination resistor. As far as the signal source is
concerned, a terminated transmission line looks just like
a resistor whose value is equal to Zo. The distributed
inductance and capacitance of the transmission line
completely disappear as far as the source is concerned.
 The only difference between a purely resistive load
and a terminated transmission line is that the signal
reaching the termination resistor is delayed by the
propagation delay of the transmission line. Also it
is important to note that while the termination
resistor is usually connected to ground, it can be
set to any DC voltage and the transmission line will
still be properly terminated.
Series
Resistor,
RS
DUT
Output
Tester Instrument and Connecting Cable
Transmission Line,
Characteristic
Impedance = Zo
Series
Resistor,
RS
DUT
Output
Termination
Resistor,
RT=Zo
Equivalent Load
Termination
Resistor,
RT=Zo
Transmission Lines

Transmission Line Termination

The ability to treat a terminated transmission line as
a purely resistive element is very useful. Many tester
instruments are connected to the DUT through a 50
 transmission line which is terminated with a 50 
resistor at the instrument’s input (on the previous
slide). As far as the DUT is concerned, this
instrument looks just like a 50  resistor attached
between its output and ground. If the DUT output is
unable to drive such a low impedance, then we can
add a resistor, RS, between the DUT output and the
terminated transmission line. The DUT output then
sees a purely resistive load equal to RS+Zo. The
signal amplitude is reduced by a factor of Zo/(Zo+RS),
but we can compensate for this gain error using a
calibration factor.
Transmission Lines

Transmission Line Termination

If we observe the signals at the DUT output, the
input to the transmission line, and the input to the
tester instrument, we can see the effects of the
resistive divider and the propagation delay of the
transmission line. The signal is attenuated by the
series resistor and termination resistance, and it is
also delayed by a time equal to Td.
DUT
Output
Transmission
Line Input
Tester
Instrument
Input
Td
Transmission Lines

Transmission Line Termination

Another method of transmission line termination is the
source termination scheme. In this scheme, the
transmitted signal is allowed to reflect off the
unterminated far end of the transmission line and is
absorbed at the source end.
Source
Output
Transmission
Line Input
Transmission
Line Midpoint
Td
Transmission
Line Output
Td
2*Td
Transmission Lines

Transmission Line Termination

One of the common mistakes made by novice test
engineers is to observe the output of a digital
channel at the point where the DIB connects to the
test head. Such an observation point represents an
intermediate point along the cascaded transmission
line. As a result, a rising edge will appear as a pair
of transitions rather than a single transition. The
novice test engineer often thinks the tester driver is
defective, when in fact it is working just fine. The
only way to see the correct signal is to observe it at
the DUT’s input.
Transmission Lines

Transmission Line Termination

Notice that we can measure the propagation delay of a
transmission line by measuring the time between the first
and second step transitions at the source end of a sourceterminated transmission line. This time is equal to 2*Td.
We can divide the measured time by two to calculate the
transmission line’s propagation delay. This is how modern
testers measure the propagation delays from the digital
channel card drivers to the DUT’s digital inputs. The tester
can automatically compensate for the electrical delay in
each transmission line, thereby removing timing skew from
the digital signals. This deskewing process is known as
time domain reflectometry, or TDR.
• Don't know which wire is A and B? When idle, B is more positive
than A.
• You don't always have to use TP cables. For small distances and
low speeds, common telephone cables are good enough.
• Termination is not critical for small distances and low speeds works fine with MAX circuits
This table is for orientation only, but still very useful:
Data transfer speed
1200bd 2400bd 4800bd 9600bd 19200bd 38400bd 57600bd
Max. cable capacity
250nF
120nF
60nF
30nF
15nF
750pF
500pF
115200bd
250pF
The Most used CRC polynomials
Following is a list of the most used CRC polynomials
•CRC-12: X^12+X^11+X^3+X^2+X+1
•CRC-16: X^16+X^15+X^2+1
•CRC-CCITT: X^16+X^12+X^5+1
•CRC-32:
X^32+X^26+X^23+X^22+X^16+X^12+X^11+X^10+X^8+X^7+X^
5+X^4+X^2+X+1
The CRC-12 is used for transmission of streams of 6-bit characters and
generates 12-bit FCS. Both CRC-16 and CCRC-CCITT are used for 8 bit
transmission streams and both result in 16 bit FCS. The last two are
widely used in the USA and Europe respectively and give adequate
protection for most applications. Applications that need extra protection
can make use of the CRC-32 which generates 32 bit FCS. The CRC-32 is
used by the local network standards committee (IEEE-802) and in some
DOD applications.
2.2 Synchronous Serial Communication
2.2.1 I2C
I2C Serial lnterface
SDA : Serial Data
SCL : Serial Clock
Normal : 100 KHz.
Fast mode : 400 Khz.
HS-mode : 3400 KHz.
Vdd : 2.3 - 5.5 V
The I C BUS
2
(Inter - Integrated Circuit)
· A 2 wire serial data and control bus
· Implemented with one serial data (SDA) and one clock
(SCL) line.
· Unique start and stop conditions.
· Slave selection protocol uses a 7-Bit slave address.
· Bi-directional data transfer.
· Acknowledgement after each byte transferred.
· No limit on the number of bytes transferred.
· Real multimaster capability.
I2C Bus Features
· Clock synchronization.
· Arbitration procedure.
· Transmission speed up to 400Khz
· Maximum bus length of 4 meters.
· Maximum drive capacity of 400pF.
· Allows series resistor for IC protection.
· Compatible with most IC technologies (TTL,
CMOS,Etc.).
I2C Definitions
MASTER:
· Initiates a transfer by generating start and
stop conditions.
· Generates the clock.
· Transmits the slave address.
· Determines data transfer direction.
SLAVE:
· Responds only when addressed.
· Timing is controlled by the clock line.
Master/Slave - Tx/Rx
I2C Hardware Details
· Devices connected to the bus must have an open drain or
open collector output for serial clock and data.
· The device must also be able to sense the logic level on
these pins.
· All devices must have a common reference ground.
· The serial clock and data lines are connected to VCC
through pull up resistors.
· At any given moment the I2C bus is:
Idle,
in Master transmit mode,
Connection
R/W = 1 : READ
R/W = 1 : WRITE
The Open Drain Configuration of I2C Circuits
+VDD
Pull-up
Resistors
SDA
SCL
Rp
Rp
Serial data line
Serial clock line
SCLK1
OUT
DATA1
OUT
SCLK2
OUT
DATA2
OUT
SCLK
IN
DATA
IN
SCLK
IN
DATA
IN
DEVICE 1
DEVICE 2
I2C devices are wire ANDed together.
Start and Stop Conditions
· A transition of the data line, when the clock line is high,
is defined as either a start or a stop condition.
· Both start and stop conditions are generated by bus
master.
· The Bus is busy after a start condition.
SDA
SDA
SCL
SCL
P
Stop
Condition
S
Start
Condition
START/STOP
Master Generates Start/Stop
START:
- SDA : HIGH -> LOW
- SDL : HIGH
STOP:
- SDA : LOW -> HIGH
- SDL : HIGH
Bit Transfer on the I2C Bus
· In normal data transfer, the data line only
changes state when the clock is low.
SDA
SCL
Data line
stable:
Data valid
Change
of data
allowed
I2C Address
· Each node has a unique 7 bit address.
· Peripherals usually have fixed and
programmable address portions.
· Addresses starting with 0000 or 1111 have
special functions.
· 0000000 is a general call address.0
· 0000001 is a null address.
· 1111xxxx is reserved for future bus expansion
First Byte Transmitted on the I2C Bus
MSB
LSB
R/W
7-bit slave address
R/W :
0 - Slave will be written by master.
1 - Slave will be read by master.
ACK
Data Format
Acknowledgement
· Master/slave receivers pull data line low for
one clock pulse after reception of a byte.
· Master receiver leaves data line high after
receipt of the last byte requested.
· Slave receiver leaves data line high on the
byte following the last byte it can accept.
ACK
ACK
- TX : SDA=1
- RX : SDA=0
NACK
- TX : SDA=1
- RX : SDA=1
Data Transfer on the I2C Bus
SDA
MSB
SCL
S
START
CONDITION
1
2
7
8
9
ACK
1
2
3-8
9
ACK
P
STOP
CONDITION
Possible Data Formats
· Master Write:
S
SLAVE ADDRESS
W
A
DATA
A
DATA
A
P
NA
P
Acknowledge from slave
· Master Read:
S
SLAVE ADDRESS
R
A
DATA
A
DATA
Acknowledge from master
Acknowledge from slave
No acknowledge from master
I2C Clock Synchronization
· Clock synchronization is used to synchronize arbitrating
masters.
· It can also be used as a handshake by a slave device to
slow data transfer from a master.
The clock synchronization procedure consists of two
algorithms:
1) If the clockline goes low when a master is asserting a
high,
the master asserts a low and starts to time out its low
clock period.
2) When a master stops asserting a low on the clock line, it
waits until the clockline actually goes high before
starting to time the high period.
SYNCHRONIZATION
T(HIGH)
T(LOW)
I2C-Bus Clock Synchronization Procedure
Wait State
CLK 1
CLK 2
SCL
Start counting
low period
Start counting
high period
Multimaster I2C Systems
Multimaster situations require two additional features of the
I2C protocol.
ARBITRATION:
· Arbitration is the procedure by which competing masters
decide final control of the bus.
· I2C arbitration does not corrupt the data transmitted by the
prevailing master.
Arbitration is performed bit by bit until it is uniquely
resolved.
· Arbitration is lost by a master when it attempts to assert a
high on the data line and fails..
Arbitration Procedure Between Two Masters
Transmitter 1 loses arbitration
DATA1
DATA2
SDA
SCL
1
2
3
4
5
ARBITRATION
I2C Family ICs
· Microcontrollers
· Microprocessors
· General Purpose Peripherals
I/O, Memory, Display, DAC, ADC,
Clock/Calendar
· Peripherals for Specific Target Martkets
Audio, Telephony, Video
ACCESS.bus .1
DEC has invented an interconnect method for connecting a PC
or Workstation to
low speed I/O devices such as:
· Keyboards
· Mouses
· Trackballs
· Tablets
· Low speed printers
· Modems
This interconnect method, known as ACCESS.bus, is based o
the I2C serial protocol invented by Philips.
ACCESS.bus .2
ACCESS.bus features:
· 80 KBps Peak Bandwidth
· Hot plugging and unplugging of devices (keyboard,
mouse, etc.)
· Up to 14 devices
· Up to 8 Meters (26.4 feet) in length
· Serial, daisy-chained 4-pin cable (2 pins are power
and ground). Only ONE device port needed on
computer.
ACCESS Bus .3
ACCESS.Bus features:
· Layered 3-layer protocol defined by DEC:
· Physical layer is I2C.
· Base Protocol over I2C defines the structure of I2C
messages and defines Control and Status Messages. Also
supports auto-addressing and hot plugging.
· Applications Protocol defines message semantics for
particular device types.
· Extremely low cost implementation based on off-the-shelf
Microcontrollers with I2C such as the Signetics 83/87C751
(used in new DEC workstation ).
ACCESS.Bus .4
· Device address and type recognition is automatic. No
drivers have to be loaded.
· Concise protocol. Only 7 standard message types. Fully
implemented in the 87C751 with 2K of Program memory.
· ACCESS.Bus is part of DEC's ARC and ACE platforms.
· Fully open and free. No royalties.
· DEC and Signetics will provide Developer's Kit with all
information required to to develop applications.
· DEC's TRI/ADD developer program will provide technical
support, documentation and updates, technical
seminars, and newsletters and assist with marketing
support.
ACCESS.bus .5
The closest thing to the ACCESS.bus is Apple's ADB (Apple
Desktop Bus). The following is a comparison between ADB
and ACCESS.bus:
ADB
ACCESS.bus
Hot-Plugging
not recommended fully supported
Peak data rate
10 KBits/sec
80 KBits/sec
Daisy-chain limit
3 devices
14 devices
3rd party access
Proprietary
Open. No royalties
Max. cable length
5 meters
8 meters
Application Example
LM75A is part of this technology,
introduced in 1999
Distinguished from all others in
temperature resolution, 0.125o C vs. 0.5o
C from competition - accuracy of ± 2o C,
frequency readout of 10 Hz
Purpose of project is to show customers
the capabilities of the LM75A
From Philips Semiconductor LM75A Data Sheet
address
bits
I2C
bus
overtemp
shutdown
Typical Connection of One LM75A Chip
(From Philips Semiconductor LM75A Data Sheet)
;**********************************
;*
WRITE INTO EEPROM
*
;*
WRITES THE DATA IN SAB0 ONTO
*
;*
ADDRESS IN SAB1 VIA I^C BUS
*
;*
USES REGISTER BANK 1
*
;**********************************
WRITEEP:
PUSH
ACC
PUSH
PSW
SETB
RS0
CLR
RS1
CALL
STARTEEP
JB
PROTECT,WPEIGHT
(PROTECTED AREA)
MOV
JMP
WPEIGHT: MOV
SAB2,#10100000B
; START CONDITION
; IS IT REQUEST TO 8th PAGE
; SLAVE ADDRESS + WRITE
NORWEEP
SAB2,#10101110B
; SLAVE ADDRESS=PAGE8 + WRITE
NORWEEP:
CALL
TRANSIC
NOP
NOP
MOV
SAB2,SAB1
CALL
TRANSIC
; WORD ADDRESS
NOP
NOP
MOV
SAB2,SAB0
CALL
TRANSIC
; DATA
NOP
NOP
CALL
STOPEEP
; STOP CONDITION
CALL
DELAYEEP
; 10 ms DELAY FOR EEPROM
POP
PSW
POP
ACC
RET
;**********************************
;*
READ FROM
EEPROM
*
;*
READS THE DATA SAB0 FROM
*
;*
ADDRESS IN SAB1 VIA I^C BUS
*
;*
USES REGISTER BANK 1
*
;**********************************
READEEP: PUSH
ACC
PUSH
PSW
SETB
RS0
CLR
RS1
CALL
STARTEEP
; START CONDITION
JB
PROTECT,RPEIGHT
; IS IT A READ REQUEST FROM PROTECTED AREA
MOV
JMP
RPEIGHT: MOV
NORREEP: CALL
SAB2,#10100000B
NORREEP
SAB2,#10101110B
; SLAVE ADDRESS=8 + WRITE
TRANSIC
MOV
SAB2,SAB1
CALL
TRANSIC
NOP
NOP
CALL
; SLAVE ADDRESS + WRITE
STARTEEP
; WORD ADDRESS
JB
PROTECT,RPEIGHT2
MOV
SAB2,#10100001B
JMP
NORREEP2
MOV
SAB2,#10101111B
; SALVE DEVICE ADDRESS=P0 + READ
RPEIGHT2:
; SLAVE DEVICE ADDRESS=P8 + READ
NORREEP2:
CALL
TRANSIC
NOP
CALL
RECEIC
MOV
SAB0,SAB2
CALL
STOPEEP
; STOP CONDITION
CALL
DELAYEEP
; 10 ms DELAY FOR EEPROM
POP
PSW
POP
ACC
RET
;***********************************
;*
START CONDITION OF EEPROM
*
;***********************************
STARTEEP:
CLR
SCL
SETB
SDA
NOP
NOP
SETB
SCL
NOP
CLR
SDA ; START CONDITION
NOP
CLR
NOP
RET
SCL
;***********************************************
;*
TRANSMIT DATA IN SAB2 VIA
I^2C
BUS
*
;***********************************************
TRANSIC:
UNCOMP:
MOV
R1,#8
MOV
A,SAB2
RLC
A
MOV
SDA,C
NOP
SETB
SCL
NOP
NOP
CLR
SCL
NOP
DJNZ
R1,UNCOMP
SETB
SDA
NOP
NOP
SETB
SCL
NOP
MOV
C,SDA
NOP
CLR
NOACKN:
RET
SCL
;
GET ACKNOWLEDGE
;***********************************************
;*
RECEIVE DATA ONTO SAB2 VIA
I^2C
BUS
*
;***********************************************
RECEIC:
MOV
R1,#8
MOV
A,#0
SETB
SDA
UNCOMPL:
; GET A BIT
NOP
NOP
SETB
SCL
NOP
NOP
MOV
C,SDA
CLR
SCL
RLC
A
NOP
NOP
DJNZ
R1,UNCOMPL
SETB
SDA
SETB
SCL
NOP
CLR
SCL
NOP
MOV
RET
SAB2,A
;
SEND ACKNOWLEDGE=1
;******************************************
;*
10 MILLISECONDS DELAY
FOR EEPROM
*
;******************************************
DELAYEEP:
MOV
R1,#40
WTWT:
MOV
R2,#250
WWW:
DJNZ
R2,WWW
DJNZ
RET
R1,WTWT