LINER LTC4302-1

LTC4302-1/LTC4302-2
Addressable
2-Wire Bus Buffers
DESCRIPTIO
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FEATURES
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The LTC®4302-1/LTC4302-2 addressable I2C bus and
SMBus compatible bus buffers allow a peripheral board
to be inserted and removed from a live backplane without
corruption of the bus. The LTC4302-1/LTC4302-2 maintain electrical isolation between the backplane and peripheral board until their VCC supply is valid and a master
device on the backplane side addresses the LTC4302-1/
LTC4302-2 and commands them to connect. The
LTC4302-1/LTC4302-2’s ADDRESS pin provides 32 possible addresses set by an external resistive divider between VCC and GND. The LTC4302-1/LTC4302-2 work
with supply voltages ranging from 2.7V to 5.5V. The SDA
and SCL inputs and outputs do not load the bus lines when
VCC is low.
Bidirectional Buffer for SDA and SCL Lines
Increases Fanout
Connect SDA and SCL Lines with 2-Wire Bus
Commands
Prevents SDA and SCL Corruption During Live Board
Insertion and Removal from Backplane
Compatible with I2CTM Standard Mode, I2C Fast
Mode and SMBus Standards
Rise Time Accelerators on SDA, SCL Lines
1V Precharge on SDA and SCL Lines
32 Unique Addresses from a Single ADDRESS Pin
Two General Purpose Inputs-Outputs (LTC4302-1)
Translates Between 5V and 3.3V Systems
(LTC4302-2)
Small 10-Pin MSOP Package
Rise time accelerator circuitry* allows for heavier capacitive bus loading while still meeting system timing requirements. During insertion, the SDA and SCL lines are
precharged to 1V to minimize bus disturbances. Two
general purpose input/output pins (GPIOs) on the
LTC4302-1 can be configured as inputs, open-drain outputs or push-pull outputs. The LTC4302-2 option replaces
one GPIO pin with a second supply voltage pin VCC2,
providing level shifting between systems with different
supply voltages. The LTC4302-1/LTC4302-2 are available
in a 10-pin MSOP package.
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APPLICATIO S
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Live Board Insertion
5V/3.3V Level Translator
Servers
Capacitance Buffer/Bus Extender
Nested Addressing
, LTC and LT are registered trademarks of Linear Technology Corporation.
I2C is a trademark of Philips Electronics N.V.
*U.S. Patent No. 6,650,174
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TYPICAL APPLICATIO
2.7V
to
5.5V
R3
10k
R4
10k
R1
1870Ω
R2
2000Ω
C1
0.01µF
VCC
LTC4302-1
SDA
CARD SDA
SDAIN SDAOUT
SCL
CARD SCL
SCLOUT
SCLIN
CONN
ADDRESS GPIO2
GPIO1
R5
10k
Input-Output Connection tPLH
R6
10k
R7
10k
R8
1k
R9
1k
OUTPUT
SIDE
50pF
INPUT
SIDE
150pF
LED
LED
4203 TA01a
GND
0.1µs/DIV
4032 F10
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LTC4302-1/LTC4302-2
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AXI U
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ABSOLUTE
RATI GS
(Note 1)
VCC to GND ................................................. –0.3V to 7V
SDAIN, SCLIN, SDAOUT, SCLOUT,
GPIO1, CONN, GPIO2 (LTC4302-1),
VCC2 (LTC4302-2) ........................................ –0.3V to 7V
ADDRESS ....................................... –0.3V to VCC + 0.3V
Operating Temperature Range
LTC4302C-1/LTC4302C-2 ...................... 0°C to 70°C
LTC4302I-1/LTC4302I-2 .................... – 40°C to 85°C
Storage Temperature Range ................. – 65°C to 125°C
Lead Temperature (Soldering, 10 sec).................. 300°C
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PACKAGE/ORDER I FOR ATIO
ORDER PART
NUMBER
TOP VIEW
SDAIN
SCLIN
CONN
ADDRESS
GND
1
2
3
4
5
10
9
8
7
6
SDAOUT
SCLOUT
VCC
GPIO2
GPIO1
MS PACKAGE
10-LEAD PLASTIC MSOP
TJMAX = 125°C, θJA = 130°C/W
LTC4302CMS-1
LTC4302IMS-1
SDAIN
SCLIN
CONN
ADDRESS
GND
MS PART MARKING
LTYF
LTYG
ORDER PART
NUMBER
TOP VIEW
1
2
3
4
5
10
9
8
7
6
SDAOUT
SCLOUT
VCC
VCC2
GPIO1
LTC4302CMS-2
LTC4302IMS-2
MS PART MARKING
MS PACKAGE
10-LEAD PLASTIC MSOP
LTABY
LTABZ
TJMAX = 125°C, θJA = 130°C/W
Consult LTC Marketing for parts specified with wider operating temperature ranges.
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C.
VCC = 2.7V to 5.5V (LTC4302-1), VCC = VCC2 = 2.7V to 5.5V (LTC4302-2) unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Power Supply/Start-Up
VCC
Positive Supply Voltage
LTC4302-1
●
2.7
5.5
V
VCC2
Card Side Supply Voltage
LTC4302-2
●
2.7
5.5
V
ICC
Supply Current
VSDAIN = 0V, VCC = 5.5V (Note 2) LTC4302-1
●
5.9
8
mA
IVCC
VCC Supply Current
VSDAIN = 0V, VCC = VCC2 = 5.5V
(Note 2) LTC4302-2
●
3.4
5
mA
IVCC2
VCC2 Supply Current
VSDAIN = 0V, VCC = VCC2 = 5.5V
(Note 2) LTC4302-2
●
2.3
4
mA
VUVLOU
UVLO Upper Threshold
VCC Rising
●
2.5
2.7
VUVLOL
UVLO Lower Threshold
VCC Falling
VUVLO2U
VCC2 UVLO Upper Threshold
LTC4302-2
VUVLO2L
VCC2 UVLO Lower Threshold
LTC4302-2
VPRE
Precharge Voltage
SDA, SCL Floating
VTHCONN
CONN Threshold Voltage
tPHL
CONN Delay, On-Off
60
ns
tPLH
CONN Delay, Off-On
20
ns
2.35
2.5
●
V
V
2.7
2.35
V
V
●
0.8
1
1.2
V
●
0.8
1.5
2.2
V
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LTC4302-1/LTC4302-2
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating temperature range, otherwise specifications are at TA = 25°C.
VCC = 2.7V to 5.5V (LTC4302-1), VCC = VCC2 = 2.7V to 5.5V (LTC4302-2) unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
0.36
0.8
V
±5
V
µA
2.2
V
General Purpose I/Os
VLOW
I/O Logic Low Voltage
ISINK = 10mA, VCC = 2.7V
●
VHIGH
ILEAK
ISOURCE = 200µA, VCC = 2.7V
VI/O = 0V to 5.5V (Note 3)
●
VTHRESH
Input Threshold Voltage
Rise Time Accelerators
Input Mode
●
0.8
1.5
IPULLUP,AC Transient Boosted Pull-Up Current
Positive Transition on SDA, SCL,
Slew Rate = 0.8V/µs, VCC = 2.7V (Note 4)
●
1
2
Input-Output Connection
VOS
Output-Input Offset Voltage
10k to VCC on SDA, SCL Pins (Note 5),
●
0
100
CIN
VOL
Digital Input Capacitance
Output Low Voltage
(Note 9)
SDA, SCL Pins, ISINK = 3mA
●
0
ILEAK
Input Leakage Current
SDA, SCL Pins, VCC = 0V to 5.5V
Connection Circuits Inactive
I/O Logic High Voltage
I/O Leakage Current
2-Wire Digital Interface Voltage Characteristics
VLTH
Logic Threshold Voltage
ILEAK
VOL
Digital Input Leakage
Digital Output Low Voltage
2-Wire Digital Interface Timing Characteristics (Note 6)
fI2C,MAX
I2C Operating Frequency
(Note 9)
tBUF
Bus Free Time Between Stop and Start
(Note 9)
Condition
tHD,STA
Hold Time After (Repeated) Start Condition (Note 9)
tSU,STA
tSU,STO
Repeated Start Condition Setup Time
Stop Condition Setup Time
(Note 9)
(Note 9)
tHD,DATI
tHD,DATO
Data Hold Time Input
Data Hold Time Output
(Note 9)
tSU,DAT
tSP
Data Setup Time
Pulse Width of Spikes Suppressed by
the Input Filter
Data Fall Time
(Note 9)
(Note 9)
tf
●
●
●
VCC = 0V to 5.5V
IPULLUP = 3mA Into SDAIN Pin
(Notes 7, 8, 9)
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: The ICC tests are performed with the backplane-to-card connection
circuitry activated.
Note 3: When the GPIOs are in open-drain output or input mode, the logic
high voltage can be provided by a pull-up supply voltage ranging from
2.2V to 5.5V, independent of the VCC voltage.
Note 4: IPULLUP,AC varies with temperature and VCC voltage as shown in
the Typical Performance Characteristics section.
Note 5: The connection circuitry always regulates its output to a higher
voltage than its input. The magnitude of this offset voltage as a function of
2.4
0.3VCC
0.5VCC
mA
175
mV
10
0.4
pF
V
±5
µA
0.7VCC
V
±5
0.4
µA
V
600
0.75
1.3
kHz
µs
●
●
400
UNITS
45
100
ns
–30
–30
0
0
ns
ns
300
–25
600
0
900
ns
ns
50
50
150
100
250
ns
ns
300
ns
20 +
0.1CB
the pull-up resistor and VCC voltage is shown in the Typical Performance
Characteristics section.
Note 6: The specifications in this section illustrate the LTC4302-1/
LTC4302-2’s compatibility with the I2C Fast Mode, the I2C Standard Mode
and SMBus specifications. See the Timing Diagram on page 5 for
illustrations of the timing parameters.
Note 7: CB = total capacitance of one bus line in pF.
Note 8: The digital interface circuit controls the data fall time only when
acknowledging or transmitting zeros during a read operation. The inputoutput connection data and clock outputs meet the fall time specification
provided that the corresponding inputs meet the fall time specification.
Note 9: Guaranteed by design. Not subject to test.
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LTC4302-1/LTC4302-2
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TYPICAL PERFOR A CE CHARACTERISTICS
(Specifications are at TA = 25°C unless otherwise noted.)
ICC vs Temperature
Input – Output tPHL vs Temperature
6.1
100
VCC = 2.7V
5.9
VCC = 5.5V
5.7
80
VCC = 3.3V
t PHL (ns)
ICC (mA)
5.5
5.3
5.1
60
40
VCC = 5.5V
4.9
VCC = 2.7V
4.7
20
CIN = COUT = 100pF
RPULLUPIN = RPULLUPOUT = 10k
4.5
4.3
–40
25
TEMPERATURE (°C)
0
–50
85
–25
0
25
50
TEMPERATURE (°C)
75
4302 G01
4302 G02
SDA, SCL VOS
IPULLUPAC vs Temperature
12
300
VCC = 5V
8
6
VCC = 3V
4
VIN = 0V
250
VOUT – VIN (mV)
IPULLUPAC (mA)
10
100
200
150
VCC = 5V
100
VCC = 3.3V
2
50
VCC = 2.7V
0
–50
–25
0
25
50
TEMPERATURE (°C)
75
100
4302 G03
0
0
10
20
RPULLUP (KΩ)
30
40
4302 G04
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LTC4302-1/LTC4302-2
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PI FU CTIO S
SDAIN (Pin 1): Serial Data Input. Connect this pin to the
SDA bus on the backplane. Do not float.
SCLIN (Pin 2): Serial Clock Input. Connect this pin to the
SCL bus on the backplane. Do not float.
CONN (Pin 3): Register Reset and Connection Sense
Input. Driving this pin low resets the registers to their
default state: GPIOs in output open-drain high impedance
mode, rise time accelerators disabled and the input-tooutput connection disabled. Communication with the
LTC4302-1/LTC4302-2 is disabled when CONN is low.
When CONN is brought back high, the registers remain in
the default state and communication is enabled.
ADDRESS (Pin 4): 2-Wire Address Programming Input.
The 2-wire address is programmed by connecting
ADDRESS to a resistive divider between VCC and ground.
The voltage on ADDRESS is converted by an internal
analog-to-digital (A/D) converter into a 5-bit digital word.
This resulting digital code represents the least significant
five bits of the 2-wire address. 1% resistors must be used
to ensure accurate address programming. 32 unique
addresses are possible. See Table 1 for 1% resistor values
and corresponding addresses. Care must also be taken to
minimize capacitance on ADDRESS. Resistors must be
placed close to the LTC4302-1/LTC4302-2’s VCC, GND
and ADDRESS pins.
GND (Pin 5): Ground. Connect this pin to a ground plane
for best results.
GPIO1 (Pin 6): General Purpose Input/Output (GPIO1).
GPIO1 can be used as an input, an open-drain output or a
push-pull output. The N-Channel MOSFET pulldown device is capable of driving LEDs. When used in input or
open-drain output mode, the I/O pin can be pulled up to a
supply voltage ranging from 2.2V to 5.5V independent of
the VCC voltage.
GPIO2 (Pin 7, LTC4302-1): General Purpose Input/Output. GPIO2 can be used as an input, an open-drain output,
or a push-pull output. The N-Channel MOSFET pulldown
device is capable of driving LED’s. When used in input or
open-drain output mode, the I/O pin can be pulled up to a
supply voltage ranging from 2.2V to 5.5V independent of
the VCC voltage.
VCC2 (Pin 7, LTC4302-2): Card Side Supply Voltage. This
pin is a power supply pin for the card side busses. Connect
VCC2 to the card’s VCC and connect a bypass capacitor of
at least 0.01µF directly between VCC2 and GND for best
results.
VCC (Pin 8): Main Input Power Supply from Backplane.
Connect a bypass capacitor of at least 0.01µF directly
between VCC and GND for best results.
SCLOUT (Pin 9): Serial Clock Output. Connect this pin to
the SCL bus on the I/O card. Do not float.
SDAOUT (Pin 10): Serial Data Output. Connect this pin to
the SDA bus on the I/O card. Do not float.
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TI I G DIAGRA
SDA
tSU, DAT
tHD, DATO,
tHD, DATI
tSU, STA
tSP
tHD, STA
tSP
tBUF
tSU, STO
SCL
4302 TD01
tHD, STA
tf
START
CONDITION
REPEATED START
CONDITION
STOP
CONDITION
START
CONDITION
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LTC4302-1/LTC4302-2
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BLOCK DIAGRA S
LTC4302-1 Addressable 2-Wire Bus Buffer
2mA
2mA
INACC
1
SLEW RATE
DETECTOR
SLEW RATE
DETECTOR
SDAIN
OUTACC
SDAOUT
BACKPLANE-TO-CARD
CONNECTION
10
UVLO
100k
SDAIN
100k
SDAOUT
1V
PRECHARGE
100k
SCLIN
100k
SCLOUT
2mA
INACC
2
2mA
SLEW RATE
DETECTOR
SLEW RATE
DETECTOR
SCLIN
OUTACC
SCLOUT
BACKPLANE-TO-CARD
CONNECTION
9
+
100ns GLITCH
FILTER
0.55VCC
0.45VCC
–
SDAIN
+
CONNECT
VCC
100ns GLITCH
FILTER
OUT CFG2
–
2pF
VCC
RLIM
50k
4
8
VCC
+
2.5V/
2.35V
3
DIR2
DATA IN2
5-BIT
A/D
ADDRESS
DECODER
ADDRESS
CONN
GPIO2
2-WIRE
DIGITAL
INTERFACE
1µs
FILTER
7
VCC
ADDRESS
FIXED BITS
“11”
UVLO
OUT CFG1
–
GPIO1
DIR1
DATA IN1
INACC
OUTACC
GND
6
5
4302 BD1
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LTC4302-1/LTC4302-2
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BLOCK DIAGRA S
LTC4302-2 Addressable 2-Wire Bus Buffer
VCC
VCC2
2mA
SLEW RATE
DETECTOR
INACC
1
2mA
SLEW RATE
DETECTOR
SDAIN
SDAOUT
BACKPLANE-TO-CARD
CONNECTION
CONNECT
VCC2
UVLO2
UVLO1
100k
100k
SDAIN
SDAOUT
1V
PRECHARGE
100k
SCLIN
VCC
100k
SCLOUT
VCC2
2mA
2mA
SLEW RATE
DETECTOR
INACC
SLEW RATE
DETECTOR
SCLIN
OUTACC
SCLOUT
BACKPLANE-TO-CARD
CONNECTION
CONNECT
+
10
CONNECT
VCC1
2
OUTACC
9
CONNECT
100ns GLITCH
FILTER
0.55VCC
0.45VCC
–
SDAIN
+
CONNECT
VCC
100ns GLITCH
FILTER
OUT CFG1
–
2pF
VCC
50k
4
8
2.5V/
2.35V
7
VCC2
DIR1
DATA IN1
6
5-BIT
A/D
ADDRESS
DECODER
ADDRESS
VCC
GPIO1
2-WIRE
DIGITAL
INTERFACE
ADDRESS
FIXED BITS
“11”
UVLO1
+
1µs
FILTER
–
UVLO2
INACC
OUTACC
GND
5
+
1µs
FILTER
–
3
CONN
4302 BD2
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LTC4302-1/LTC4302-2
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OPERATIO
Live Insertion and Start-Up
The LTC4302 allows I/O card insertion into a live backplane without corruption of the data and clock busses
(SDA and SCL). In its main application, the LTC4302
resides on the edge of a peripheral card with the SCLOUT
pin connected to the card’s SCL bus and the SDAOUT
connected to the card’s SDA bus. If a card is plugged into
a live backplane via a staggered connector, ground and
VCC make connection first. The LTC4302 starts in an
undervoltage lockout (UVLO) state, ignoring any activity
on the SDA and SCL pins until VCC rises above 2.5V
(typical). This ensures that the LTC4302 does not try to
function until it has sufficient bias voltage.
During this time, the 1V precharge circuitry is also active
and forces 1V through 100k nominal resistors to the SDA
and SCL pins. The concept of initializing the SDA and SCL
pins before they make contact with a live backplane is
described in the CompactPCITM specification. Because the
I/O card is being plugged into a live backplane, the voltage
on the SDA and SCL busses may be anywhere between 0V
and VCC. Precharging the SCL and SDA pins to 1V minimizes the worst-case voltage differential these pins will
see at the moment of connection, therefore minimizing the
amount of disturbance caused by the I/O card. The
LTC4302-1 precharges all four SDA and SCL pins whenever the VCC voltage is below its UVLO threshold voltage.
The LTC4302-2 precharges SDAIN and SCLIN whenever
VCC is below its UVLO threshold and precharges SDAOUT
and SCLOUT whenever VCC2 is below its UVLO threshold.
After ground and VCC connect, SDAIN and SCLIN make
connection with the backplane SDA and SCL lines. Once
the part comes out of UVLO, the precharge circuitry is shut
off. Finally, the CONN pin connects to the short CONN pin
on the backplane, the 2-wire bus digital interface circuitry
is activated and a master on the bus can write to or read
from the LTC4302.
General I2C Bus/SMBus Description
The LTC4302 is designed to be compatible with the I2C and
SMBus two wire bus systems. I2C Bus and SMBus are
reasonably similar examples of two wire, bidirectional,
serial communication busses; however, calling them two
wire is not strictly accurate, as there is an implied third
wire which is the ground line. Large ground drops or
spikes between the grounds of different parts on the bus
can interrupt or disrupt communications, as the signals on
the two wires are both inherently referenced to a ground
which is expected to be common to all parts on the bus.
Both bus types have one data line and one clock line which
are externally pulled to a high voltage when they are not
being controlled by a device on the bus. The devices on the
bus can only pull the data and clock lines low, which makes
it simple to detect if more than one device is trying to
control the bus; eventually, a device will release a line and
it will not pull high because another device is still holding
it low. Pullups for the data and clock lines are usually
provided by external discrete resistors, but external current sources can also be used. Since there are no dedicated lines to use to tell a given device if another device is
trying to communicate with it, each device must have a
unique address to which it will respond. The first part of
any communication is to send out an address on the bus
and wait to see if another device responds to it. After a
response is detected, meaningful data can be exchanged
between the parts.
Typically, one device controls the clock line at least most
of the time and normally sends data to the other parts and
polls them to send data back. This device is called the
master. There can be more than one master, since there is
an effective protocol to resolve bus contentions, and nonmaster (slave) devices can also control the clock to delay
rising edges to give themselves more time to complete
calculations or communications (clock stretching). Slave
devices need to control the data line to acknowledge
communications from the master. Some devices need to
send data back to the master; they will be in control of the
data line while they are doing so. Many slave devices have
no need to stretch the clock signal, which is the case with
the LTC4302.
Data is exchanged in the form of bytes, which are 8-bit
packets. Any byte needs to be acknowledged by the slave
or master (data line pulled low) or not acknowledged by
the master (data line left high), so communications are
CompactPCI is a trademark of the PCI Industrial Computer Manufacturers
Group.
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LTC4302-1/LTC4302-2
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OPERATIO
broken up into 9-bit segments, one byte followed by one
bit for acknowledging. For example, sending out an address consists of 7-bits of device address, 1-bit that
signals whether a read or write operation will be performed and then 1 more bit to allow the slave to acknowledge. There is no theoretical limit to how many total bytes
can be exchanged in a given transmission.
byte of information was received. The acknowledge related clock pulse is generated by the master. The transmitter master releases the SDA line (HIGH) during the acknowledge clock pulse. The slave-receiver must pull down
the SDA line during the acknowledge clock pulse so that it
remains stable LOW during the HIGH period of this clock
pulse.
I2C and SMBus are very similar specifications, SMBus
having been derived from I2C. In general, SMBus is
targeted to low power devices (particularly battery powered ones) and emphasizes low power consumption while
I2C is targeted to higher speed systems where the power
consumption of the bus is not as critical. I2C has three
different specifications for three different maximum speeds,
these being standard mode (100kHz max), fast mode
(400kHz max), and Hs mode (3.4MHz max). Standard and
fast mode are not radically different, but Hs mode is very
different from a hardware and software perspective and
requires an initiating command at standard or fast speed
before data can start transferring at Hs speed. SMBus
simply specifies a 100kHz maximum speed.
When a slave-receiver doesn’t acknowledge the slave
address (for example, it’s unable to receive because it’s
performing a real-time function), the data line must be left
HIGH by the slave. The master can then generate a STOP
condition to abort the transfer.
The START and STOP Conditions
When the bus is not in use, both SCL and SDA must be
high. A bus master signals the beginning of a transmission
with a START condition by transitioning SDA from high to
low while SCL is high. When the master has finished
communicating with the slave, it issues a STOP condition
by transitioning SDA from low to high while SCL is high.
The bus is then free for another transmission.
Acknowledge
The acknowledge signal is used for handshaking between
the master and the slave. An acknowledge (LOW active)
generated by the slave lets the master know that the latest
If a slave receiver does acknowledge the slave address but
some time later in the transfer cannot receive any more
data bytes, the master must again abort the transfer. This
is indicated by the slave not generating the acknowledge
on the first byte to follow. The slave leaves the data line
HIGH and the master generates the STOP condition. When
the master is reading data from the slave, the master
acknowledges each byte read except for the last byte read.
The master signals a not acknowledge when no other data
is to be read and carries out the STOP condition.
Address Byte and Setting the LTC4302’s Address
The LTC4302’s address is set by connecting ADDRESS to
a resistive divider between VCC and ground. The voltage on
ADDRESS is converted into a 5-bit digital word by an A/D
converter, as shown in Figure 1. This 5-bit word sets the
5 LSB’s of the LTC4302’s address; its two MSB’s are
always “11”. Using 1% resistors, the voltage at ADDRESS
is set 0.5LSB away from each code transition. For example, with VCC=5V, 1LSB=5V/32 codes = 156.25mV/
code. To set an address of 00, set ADDRESS to 0V +
0.5LSB = 78.125mV.
VCC
R1
ADDRESS
4
R2
5 WIRE
5-BIT
A/D
4302 F01
Figure 1. Address Compare Circuitry
sn430212 430212fs
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LTC4302-1/LTC4302-2
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Table 1. Suggested ADDRESS 1% Resistor Values
(Refer to Figure 1 for R1 and R2)
ADDRESS
CODE
R1(TOP)
RESISTOR
R2(BOTTOM)
RESISTOR
5V IDEAL
VOLTAGE
ALLOWED ADDRESS
VOLTAGE RANGE
3.3V IDEAL
VOLTAGE
ALLOWED ADDRESS
VOLTAGE RANGE
00
8660
137
0.078125
0.076 to 0.079
0.051563
0.050 to 0.052
01
2800
137
0.234375
0.229 to 0.238
0.154688
0.151 to 0.157
02
1180
100
0.390625
0.383 to 0.398
0.257813
0.253 to 0.263
03
1370
169
0.546875
0.539 to 0.559
0.360938
0.356 to 0.369
04
1070
174
0.703125
0.687 to 0.711
0.464063
0.454 to 0.470
05
1070
221
0.859375
0.842 to 0.870
0.567188
0.556 to 0.574
06
4120
1050
1.015625
0.999 to 1.032
0.670313
0.660 to 0.681
07
3320
1020
1.171875
1.157 to 1.193
0.773438
0.764 to 0.788
08
3160
1150
1.328125
1.315 to 1.354
0.876563
0.868 to 0.893
09
6490
2740
1.484375
1.464 to 1.505
0.979688
0.966 to 0.993
10
2150
1050
1.640625
1.619 to 1.663
1.082813
1.068 to 1.097
11
2050
1150
1.796875
1.774 to 1.820
1.185938
1.171 to 1.201
12
2150
1370
1.953125
1.922 to 1.970
1.289063
1.269 to 1.300
13
1960
1430
2.109375
2.085 to 2.134
1.392188
1.376 to 1.408
14
2100
1740
2.265625
2.241 to 2.290
1.495313
1.479 to 1.512
15
2000
1870
2.421875
2.391 to 2.441
1.598438
1.578 to 1.611
16
1870
2000
2.578125
2.559 to 2.609
1.701563
1.689 to 1.722
17
1740
2100
2.734375
2.710 to 2.759
1.804688
1.788 to 1.821
18
1430
1960
2.890625
2.866 to 2.915
1.907813
1.892 to 1.924
19
1370
2150
3.046875
3.030 to 3.078
2.010938
2.000 to 2.031
20
1150
2050
3.203125
3.180 to 3.226
2.114063
2.099 to 2.129
21
1050
2150
3.359375
3.337 to 3.381
2.217188
2.203 to 2.232
22
2740
6490
3.515625
3.495 to 3.537
2.320313
2.307 to 2.334
23
1150
3160
3.671875
3.646 to 3.685
2.423438
2.407 to 2.432
24
1020
3320
3.838125
3.807 to 3.843
2.526563
2.512 to 2.536
25
1050
4120
3.984375
3.968 to 4.001
2.629688
2.619 to 2.640
26
221
1070
4.140625
4.130 to 4.158
2.732813
2.726 to 2.744
27
174
1070
4.296875
4.289 to 4.313
2.835938
2.830 to 2.846
28
169
1370
4.453125
4.441 to 4.461
2.939063
2.931 to 2.944
29
100
1180
4.609375
4.602 to 4.617
3.042188
3.037 to 3.047
30
137
2800
4.765625
4.762 to 4.771
3.145313
3.143 to 3.149
31
137
8660
4.921875
4.921 to 4.924
3.248438
3.248 to 3.250
Select standard 1% tolerance resistor values that most
closely match the ideal resistor values. Table 1 shows
recommended values for each of the code segments. For
code 00, RTOP=8660Ω, RBOTTOM=137Ω. This yields a
voltage of 77.87mV. Resistors must be placed close to the
LTC4302’s VCC, GND and ADDRESS pins. Care must also
be taken to minimize capacitance on ADDRESS.
In two-wire bus systems, the master issues the Address
Byte immediately following a Start Bit. The first seven bits
contain the address of the slave device being targeted by
the master. If the first two MSB’s are 1’s, and the next 5 bits
match the output of the LTC4302’s 5-bit address A/D, an
address match occurs, and the LTC4302 acknowledges
the Address Byte and continues communicating with the
sn430212 430212fs
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LTC4302-1/LTC4302-2
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OPERATIO
master. The 8th bit of the Address Byte is the Read/Write
bit (R/W) and determines whether the master is writing to
or reading from the slave. Figure 2 shows a timing diagram
of the Start Bit and Address Byte required for both reading
and writing the LTC4302.
Table 2. Register 1 Definition
BIT
NAME
TYPE
FUNCTION
7 (MSB) CONNECT Read/Write Backplane-to-Card Connection;
0 = Disconnected, 1 = Connected
6
DATA IN2 Read/Write Logic State of Input Signal to GPIO2
Block
Programmable Features
5
DATA IN1 Read/Write Logic State of Input Signal to GPIO1
Block
The two-wire bus can be used to connect and disconnect
the card and backplane SDA and SCL busses, enable and
disable the rise time accelerators on either or both the
backplane and card sides, and configure and write to the
two GPIO pins (only one GPIO for the LTC4302-2). The bits
that control these features are stored in two registers. For
ease of software coding, the bits that are expected to
change more frequently are stored in the first register. In
addition, the bus can be used to read back the logic states
of the control bits. The maximum SCL frequency is 400kHz.
4
DATA2
Read Only Logic State of GPIO2 Pin
3
DATA1
Read Only Logic State of GPIO1 Pin
2
NA
Read Only Never Used, Always 0
1
NA
Read Only Never Used, Always 0
0
NA
Read Only Never Used, Always 0
Default State (MSB First): 011DD000
Note: The second and third bits of the data byte are used to write the data
value of the two GPIOs. During a write operation, the five read only bits are
ignored. During a read operation, bits 7 to 3 will be shifted onto the data
bus, followed by three 0s. Also note that DATA2 and DATA IN2 are
meaningless for the LTC4302-2 because there is no GPIO2 pin for that
option.
Writing to the LTC4302
The LTC4302 can be written using three different formats,
which are shown in Figures 3, 5 and 6. Each format begins
with a Start Bit, followed by the Address Byte as discussed
above. The procedure for writing one data byte is given by
the SMBus Send Byte protocol, illustrated in Figure 3. The
bits of the Data Byte are stored in the LTC4302’s Register
1. Table 2 defines the functions of these control bits. The
MSB controls the connection between the backplane and
SDA
a6 - a0
SCL
1-7
card two-wire busses. The next two bits are used to write
logic values to the two GPIO pins. Since the LTC4302-2
has only one GPIO pin, bit “DATA IN1” controls its logic
value and bit “DATA IN2” is ignored. The 5 LSBs are not
used in Write operations.
The LTC4302 can be written with two data bytes by using
the format shown in Figure 5. The Address Byte and first
Data Byte are exactly the same as they are for the Send Byte
b7 - b0
8
9
1-7
b7 - b0
8
9
1-7
8
9
S
START
CONDITION
P
ADDRESS
R/W
ACK
DATA
ACK
DATA
ACK
STOP
CONDITION
4302 F02
Figure 2. Data Transfer Over I2C or SMBus
1
7
1
1
8
1
1
START
11 a4 - a0
WR
ACK
d7 - d0
ACK
STOP
SLAVE
ADDRESS
0
S
0
DATA
BYTE
S
0
4302 F03
Figure 3. Writing One Byte Using Send Byte Protocol
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Table 3. Register 2 Definition
VCC
BIT
NAME
7 (MSB)
DIR2
Read/Write GPIO2 Mode; 0 = Output, 1 = Input*
DIR1
Read/Write GPIO1 Mode; 0 = Output, 1 = Input
6
5
4
3
TYPE
FUNCTION
OUT CFG2
GPIO2
OUT CFG2 Read/Write GPIO2 Output Mode; 0 = Open Drain,
1 = Push-Pull†*
OUT CFG1 Read/Write GPIO1 Output Mode; 0 = Open Drain,
1 = Push-Pull†
OUTACC
Read/Write Card Side Rise Time Accelerator
Contol; 0 = Disabled, 1 = Active
2
INACC
1
NA
Read Only
Never Used, Always 1
0
NA
Read Only
Never Used, Always 1
VCC
Read/Write Backplane Side Rise Time Accelerator
Control; 0 = Disabled, 1 = Active
OUT CFG1
GPIO1
DIR1
DATA IN1
Default State (MSB First): 00000011
†OUT CFG1 has no effect when DIR1 = 1; OUT CFG2 has no effect when
DIR2 = 1.
*DIR2 and OUT CFG2 apply only to the LTC4302-1; there is no GPIO2 for
the LTC4302-2, so these bits are meaningless in this case.
6
4302 F04
Figure 4. GPIO Circuits and Their Control Bits
that control their operation. The 2 LSB’s are not used in
Write operations.
protocol. After the first Data Byte, the master transmits a
second Data Byte, followed by a Stop Bit. The bits of the
second Data Byte are stored in the LTC4302’s Register 2.
Table␣ 3␣ defines the functions of these control bits. The
first 4 MSB’s control the input/output configurations of the
two GPIO pins. The next 2 bits control the enabling/
disabling of the card side and backplane side rise time
accelerators respectively. Since the LTC4302 -2 has only
one GPIO pin, “DIR1” and “OUT CFG1” control its configuration, and “DIR2” and “OUT CFG2” are ignored. Figure 4
shows a schematic of the two GPIOs and the register bits
The LTC4302 can also be written with two bytes using the
SMBus Write Word protocol, as shown in Figure 6. The
LTC4302 treats the first two bytes after the Address Byte
(which the Write Word protocol refers to as “Command
Code” and “Data Byte Low”) as the two Data Bytes, and
stores these bytes in Registers 1 and 2 respectively. After
the master transmits the “Data Byte High” byte, the
LTC4302 acknowledges reception of the byte but ignores
the data contained therein.
1
7
1
1
8
1
8
1
1
START
11 a4 - a0
WR
ACK
d7 - d0
ACK
d7 - d0
ACK
STOP
0
S
0
DATA
BYTE 1
S
0
DATA
BYTE 2
S
0
SLAVE
ADDRESS
7
DIR2
DATA IN2
4302 F05
Figure 5. Writing Two Bytes
1
7
1
1
8
1
8
1
8
1
1
START
11 a4 - a0
WR
ACK
d7 - d0
ACK
d7 - d0
ACK
XXXXXXXX
ACK
STOP
SLAVE
ADDRESS
0
S
0
COMMAND
CODE
S
0
DATA
BYTE LOW
S
0
DATA
BYTE HIGH
S
0
4302 F06
Figure 6. Writing Two Bytes Using SMBus Write Word Protocol
sn430212 430212fs
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LTC4302-1/LTC4302-2
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Data Transfer Timing for Write Commands
the first 5 bits contain useful information to be read. The
two added bits indicate the logic state of the GPIO pins.
The 3 LSBs are not used and are always “000.”
In order to help ensure that bad data is not written into the
LTC4302, data from a write command is only stored after
a valid Stop Bit has been performed. If a Start Bit occurs
after new data bytes have been written but before a Stop
Bit is issued, the new data bytes are lost. In this case, the
master must readdress the part, rewrite the data bytes and
issue a Stop Bit before issuing any Start Bits to properly
update the registers. Also note that driving the CONN pin
low asynchronously resets the registers to their default
states, as specified in Tables 2 and 3. When CONN is driven
back high, the registers remain in the default state.
The format for reading two data bytes is shown in Figure
8. The Address Byte and first Data Byte are exactly the
same as they are for the Receive Byte protocol. After the
first Data Byte, the master transmits an Acknowledge
indicating that it wants to read another data byte. The bits
contained in Register 2 are then written onto the bus as
“Data Byte 2.” Table 3 defines the functions of these
control bits. The 2 LSB’s are not used and are always “11.”
The master signals a not acknowledge after the last
byte read.
Reading from the LTC4302
The SMBus Read Word protocol can also be used to read
two bytes from the LTC4302, as shown in Figure 9. Note
that the first Address Byte and the Command Code constitute a write operation. However, because these bytes are
followed immediately by a Start Bit and not a Stop Bit, the
data contained in the Command Code is not written into
the LTC4302. After the second Start Bit, the format is
exactly the same as shown in Figure 8.
The LTC4302 can be read using three different formats, as
shown in Figures 7 through 9. Each format begins with a
Start Bit, followed by the Address Byte, as discussed
above. The procedure for reading one data byte is given by
the SMBus Receive Byte protocol, illustrated in Figure 7.
The bits of the Data Byte are read from the LTC4302’s
Register 1. Table 2 defines the functions of these control
bits. While only the first 3 bits of Register 1 can be written,
1
7
1
1
8
1
1
START
11 a4 - a0
RD
ACK
d7 - d3 000
ACK
STOP
SLAVE
ADDRESS
1
S
0
DATA
BYTE
M
1
4302 F07
Figure 7. Reading One Byte Using Receive Byte Protocol
1
7
1
1
8
1
8
1
1
START
11 a4 - a0
RD
ACK
d7 - d3 000
ACK
d7 - d2 11
ACK
STOP
SLAVE
ADDRESS
1
S
0
DATA
BYTE 1
M
0
DATA
BYTE 2
M
1
4302 F08
Figure 8. Reading Two Bytes
8
1
1
7
1
1
8
1
8
1
1
ACK
XXXXXXXX
ACK
START
11 a4 - a0
RD
ACK
d7 - d3 000
ACK
d7 - d2 11
ACK
STOP
S
0
COMMAND
CODE
S
0
1
S
0
DATA
BYTE 1
M
0
DATA
BYTE 2
M
1
1
7
1
1
START
11 a4 - a0
WR
0
SLAVE
ADDRESS
SLAVE
ADDRESS
4302 F09
Figure 9. Reading Two Bytes Using SMBus Read Word Protocol
sn430212 430212fs
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OPERATIO
Connection Circuitry
Propagation Delays
Masters on the SDAIN and SCLIN busses can address the
LTC4302 and command it to connect SDAIN to SDAOUT
and SCLIN to SCLOUT as described in the “Write One or
Two Bytes” section. Once this connection occurs, masters
on the card are then able to read from and write to the part
via the SDAOUT and SCLOUT pins. However, whenever
the two sides are disconnected, the command to reconnect must come from SDAIN and SCLIN.
During a rising edge, the rise time on each side is determined by the combined pull-up current of the LTC4302
boost current and the bus resistor and the equivalent
capacitance on the line. If the pull-up currents are the
same, a difference in rise time occurs that is directly
proportional to the difference in capacitance between the
two sides. This effect is displayed in Figure 10 for VCC =
3.3V and a 10k pull-up resistor on each side (50pF on one
side and 150pF on the other). Since the output side has
less capacitance than the input, it rises faster and the
effective tPLH is negative.
Once the connection circuitry is activated, the functionality of the SDAIN and SDAOUT pins is identical. A low
forced on either pin at any time results in both pin voltages
being low. Masters must pull the bus voltages below 0.4V
worst-case with respect to the LTC4302’s ground pin to
ensure proper operation. SDAIN and SDAOUT enter a logic
high state only when all devices on both SDAIN and
SDAOUT busses force a high. The same is true for SCLIN
and SCLOUT. This important feature ensures that clock
stretching, clock arbitration and the acknowledge protocol
always work, regardless of how the devices in the system
are connected to the LTC4302.
OUTPUT
SIDE
50pF
INPUT
SIDE
150pF
4032 F10
Another key feature of the connection circuitry is that it
provides bidirectional buffering, keeping the backplane
and the card capacitances isolated. Because of this isolation, the waveforms on the backplane busses look slightly
different from the corresponding card bus waveforms.
Input-to-Output Offset Voltage
When a logic low voltage, VLOW1 is driven on any of the
LTC4302’s data or clock pins, the LTC4302 regulates the
voltage on the other side (VLOW2) to a slightly higher
voltage, as directed by the following equation:
Figure 10. Input-Output Connection tPLH
OUTPUT
SIDE
50pF
INPUT
SIDE
150pF
4032 F11
VLOW2 (typical) = VLOW1 + 75mV + (VBUS/R) • 70Ω
Figure 11. Input-Output Connection tPHL
where R is the bus pull-up resistance on VLOW2 in ohms
and VBUS is the supply voltage to which R is connected.
For example, if a device is forcing SDAOUT to 10mV, and
if VCC = 3.3V and the pull-up resistor R on SDAIN is 10k,
then the voltage on SDAIN = 10mV + 75mV + (3.3V/10k)
• 70Ω = 108mV (typical). See the Typical Performance
Characteristics section for curves showing the offset
voltage as a function of VCC and R.
There is a finite propagation delay, tPHL, through the
connection circuitry for falling waveforms. Figure 11 shows
the falling waveforms for the same VCC, pull-up resistors
and equivalent capacitance conditions used in Figure 10.
An external N-Channel MOSFET device pulls down the
voltage on the side with 150pF capacitance; the LTC4302
sn430212 430212fs
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LTC4302-1/LTC4302-2
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pulls down the voltage on the 50pF side with a delay of
55ns. This delay is always positive and is a function of
supply voltage, temperature and the pull-up resistors and
equivalent bus capacitances on both sides of the bus. The
Typical Performance Characteristics section shows tPHL
as a function of temperature and voltage for 10k pull-up
resistors and 100pF equivalent bus capacitance on both
sides of the part. Larger output capacitances translate to
longer delays (up to 150ns). Users must quantify the
difference in propagation times for a rising edge versus a
falling edge in their systems and adjust setup and hold
times accordingly.
General Purpose Input/Outputs (GPIOs)
The LTC4302-1 provides two general purpose input/output pins (GPIOs) that can be configured as inputs, opendrain outputs or push-pull outputs. In push-pull mode, at
VCC = 2.7V, the typical pull-up impedance is 670Ω and the
typical pull-down impedance is 35Ω, making the GPIO
pull-downs capable of driving LEDs. The user must take
care to minimize the power dissipation in the pulldown
device. LEDs should have series resistors added to limit
current and the voltage drop across the internal pulldown
if their forward drop is less than about VCC-0.7V. Pullup
resistors should be sized to allow the internal pulldowns to
pull the GPIO pins below 0.7V. In open-drain output mode,
the user provides the logic high by connecting a resistor
to an external supply voltage. The external supply voltage
can range from 2.2V to 5.5V independent of the VCC
voltage.
The LTC4302-2 replaces one GPIO pin with a VCC2 pin and
provides only one GPIO.
Rise Time Accelerators
Rise time accelerator circuits on all four SDA and SCL pins
allow the user to choose weaker DC pull-up currents on the
bus, reducing power consumption while still meeting
system rise time requirements. A master on the bus may
activate the accelerators on the backplane side, the card
side, neither or both, by writing the LTC4302’s registers as
described above. When activated, the accelerators switch
in 2mA of current at VCC = 2.7V and 9mA at VCC = 5.5V
during positive bus transitions to quickly slew the SDA and
SCL lines once their DC voltages exceed 0.6V and the initial
rise rate on the pin exceeds 0.8V/µs. Using a general rule
of 20pF of capacitance for every device on the bus (10pF
for the device and 10pF for interconnect), choose a pull-up
current so that the bus will rise on its own at a rate of at
least 0.8V/µs to guarantee activation of the accelerators.
For example, assume an SMBus system with VCC = 3.3V,
a 10k pull-up resistor and equivalent bus capacitor of
200pF. The rise time of an SMBus system is calculated
from (VIL(MAX) – 0.15V) to (VIH(MIN) + 0.15V) or 0.65V to
2.25V. It takes an RC circuit 0.92 time constants to
traverse this voltage for a 3.3V supply; in this case, 0.92 •
(10k • 200pF) = 1.84µs. Thus, the system exceeds the
maximum allowed rise time of 1µs by 84%. However,
using the rise time accelerators, which are activated at a
DC threshold below 0.65V, the worst-case rise time is
(2.25V – 0.65V) •␣ 200pF/1mA = 320ns, which meets the
1µs rise time requirement.
CONN Register Reset
Grounding CONN resets the registers to their default state
as specified in Tables 2 and 3. In the default state, the
backplane side is disconnected from the card side, the rise
time accelerators are disabled and the GPIOs are set in
open-drain output mode with the N-Channel MOSFET
open-drain pulldown turned off. Connecting a weak resistor from CONN to ground on the I/O card and using a
staggered connector with CONN connecting to the shortest pin guarantee glitch-free live board insertion and
removal. When the CONN voltage is brought back to VCC
the registers remain in the default state and can then be
read or written to.
sn430212 430212fs
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OPERATIO
Glitch Filters
The LTC4302 provides glitch filters on both the SDAIN and
SCLIN signals as required by the I2C Fast Mode (400kHz)
specification. The filters prevent signals of up to 50ns
(minimum) time duration and rail-to-rail voltage magnitude from passing into the 2-wire bus digital interface
circuitry.
Fall Time Control
Per the I2C Fast Mode (400kHz) specification, the 2-wire
bus digital interface circuitry provides fall time control
when forcing logic lows onto the SDAIN bus. The fall time
always meets the limits:
(20 + 0.1 • CB) < tf < 300ns
where tf is the fall time in ns and CB is the equivalent
capacitance on SDAIN in pF. Whenever the connection
circuitry is passing logic lows from SDAOUT to SDAIN
(and vice versa), its output signal will meet the fall time
requirements, provided that its input signal meets the fall
time requirements.
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Live Insertion and Removal, Capacitance Buffering
The application shown in Figure 12 highlights the live
insertion and removal, and capacitance buffering features
of the LTC4302. Note that if the I/O card were plugged
directly into the backplane, the card capacitance would
add directly to the backplane capacitance making rise and
fall time requirements difficult to meet. Placing a LTC4302
on the edge of the card, however, isolates the card capacitance from the backplane. The LTC4302 drives the capacitance of everything on the card, and the backplane must
drive only the capacitance of the LTC4302, which is less
than 10pF.
Assuming that a staggered connector is available, make
ground, VCC and VCC2 the longest pins to guarantee that
SDAIN and SCLIN receive the 1V precharge voltage before
they connect. Make SDAIN and SCLIN medium length pins
to ensure that they are firmly connected while CONN is
low. Make CONN the shortest pin and connect a weak
resistor from CONN to ground on the I/O card. This
ensures that the LTC4302-1/LTC4302-2 remain in a high
impedance state while SDAIN and SCLIN are making
connection during live insertion. During live removal,
having CONN disconnect first ensures that the LTC4302
enters a high impedance state in a controlled manner
before SDAIN and SCLIN disconnect. Owing to the fact
that the LTC4302 powers into a high impedance state, and
also owing to the 1V precharge voltage and the less than
10pF pin capacitance, SDAIN and SCLIN cause minimal
disturbance on the backplane busses when they make
contact with the connector.
Address Expansion with Nested Addressing
Figure 13 illustrates how the LTC4302 can be used to
expand the number of devices in a system by using nested
addressing. Note that each I/O card contains a sensor
device having address 1111 111. If the two cards are
plugged directly into the backplane, the two sensors will
require two different addresses. However, each LTC4302
isolates the devices on its card from the rest of the system
until it is commanded to connect. If masters use the
LTC4302s to connect only one I/O card at a time, then each
I/O card can have a device with address 1111 111 and no
problems will␣ occur.
sn430212 430212fs
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BACKPLANE
BACKPLANE
CONNECTOR
VCC
5V
PCB EDGE
BACKPLANE
CONNECTOR
I/O PERIPHERAL CARD
+
R1
10k
R2
10k
R3
137Ω
SDA
SCL
CONN
R5
200k
R4
8660Ω
C1
0.01µF
R6
10k
VCC
LTC4302-1
SDAIN SDAOUT
SCLOUT
SCLIN
CONN
ADDRESS GPIO2
GND
GPIO1
X1
R7
10k
R8
1k
R9
1k
CARD SDA
CARD SCL
LED
LED
4302 F12
Figure 12. LTC4302-1 in a Live Insertion and Capacitance Buffering Application
BACKPLANE
VCC
5V
I/O PERIPHERAL CARD 1
+
R1
10k
R2
10k
R3
8660Ω
C1
0.01µF
R5
10k
R6
10k
VCC
LTC4302-1
SDAIN SDAOUT
SCLOUT
SCLIN
CONN
ADDRESS GPIO2
GND
GPIO1
X1
SDA
SCL
R4
137Ω
CARD SDA
CARD SCL
SENSOR
ADDRESS = 1111 111
ADDRESS = 1100 000
I/O PERIPHERAL CARD 2
+
R7
2800Ω
R8
137Ω
C2
0.01µF
R9
10k
R10
10k
VCC
LTC4302-1
SDAIN SDAOUT
SCLOUT
SCLIN
CONN
ADDRESS GPIO2
GPIO1
GND
X2
ADDRESS = 1100 001
CARD SDA
CARD SCL
SENSOR
ADDRESS = 1111 111
4302 F13
Figure 13. LTC4302-1 in a Nested Addressing Application
sn430212 430212fs
17
LTC4302-1/LTC4302-2
U
W
U U
APPLICATIO S I FOR ATIO
5V to 3.3V Level Translator and Power Supply
Redundancy (LTC4302-2)
Systems requiring different supply voltages for the backplane side and the card side can use the LTC4302-2 as
shown in Figure 14. The pull-up resistors on the card side
connect from SDAOUT and SCLOUT to VCC2 and those on
the backplane side connect from SDAIN and SCLIN to VCC.
The LTC4302-2 functions for voltages ranging from 2.7V
to 5.5V on both VCC and VCC2. There is no constraint on the
voltage magnitudes of VCC and VCC2 with respect to each
other.
VCC
5V
R3
10k
R4
10k
R1
8660Ω
R5
10k
This application also provides power supply redundancy.
If either the VCC or VCC2 supply voltage falls below its UVLO
threshold, the LTC4302-2 disconnects the backplane from
the card so that the side that is still powered can continue
to function.
Systems with Supply Voltage Droop (LTC4302-1)
In large 2-wire systems, the VCC voltages seen by devices
at various points in the system can differ by a few hundred
millivolts or more. This situation is modelled by a series
resistor in the VCC line as shown in Figure 15. For proper
operation of the LTC4302-1, make sure that VCC(BUS) ≥
VCC(LTC4302) – 0.5V.
C2
0.01µF
R6
10k
VCC
VCC2
LTC4302-2
SDAIN SDAOUT
SCLOUT
SCLIN
CONN
ADDRESS
GPIO1
GND
SDA
SCL
R2
137Ω
R7
10k
R8
1k
CARD VCC 3.3V
C1
0.01µF
CARD SDA
CARD SCL
LED
4203 F14
Figure 14. 5V to 3.3V Level Translator Application
RDROP
VCC LOW
VCC
C1
0.01µF
R3
10k
R4
10k
R1
8660Ω
SDA
SCL
R2
137Ω
VCC
LTC4302-1
SDAIN SDAOUT
SCLOUT
SCLIN
CONN
ADDRESS GPIO2
GND
GPIO1
R5
10k
R6
10k
R7
1k
R8
1k
SDA2
SCL2
LED
LED
4203 F15
Figure 15. System with Supply Voltage Droop
sn430212 430212fs
18
LTC4302-1/LTC4302-2
U
W
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APPLICATIO S I FOR ATIO
Repeater/Bus Extender Application
and fall time specifications for up to 1nF of capacitance,
thus allowing much more interconnect distance. In this
situation, the differential ground voltage between the two
systems may limit the allowed distance because a valid
logic low voltage with respect to the ground at one end of
the system may violate the allowed VOL specification with
respect to the ground at the other end. In addition, the
connection circuitry offset voltages of the back-to-back
LTC4302-1’s add together, directly contributing to the
same problem.
Users who wish to connect two 2-wire systems separated
by a distance can do so by connecting two LTC4302-1s
back-to-back as shown in Figure 16. The I2C specification
allows for 400pF maximum bus capacitance, severely
limiting the length of the bus. The SMBus specification
places no restriction on bus capacitance; however, the
limited impedances of devices connected to the bus require systems to remain small, if rise and fall time specifications are to be met. The strong pull-up and pull-down
impedances of the LTC4302-1 are capable of meeting rise
U
PACKAGE DESCRIPTIO
MS Package
10-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1661)
0.889 ± 0.127
(.035 ± .005)
5.23
(.206)
MIN
3.20 – 3.45
(.126 – .136)
3.00 ± 0.102
(.118 ± .004)
(NOTE 3)
0.50
0.305 ± 0.038
(.0197)
(.0120 ± .0015)
BSC
TYP
RECOMMENDED SOLDER PAD LAYOUT
0.254
(.010)
10 9 8 7 6
3.00 ± 0.102
(.118 ± .004)
(NOTE 4)
4.90 ± 0.152
(.193 ± .006)
DETAIL “A”
0.497 ± 0.076
(.0196 ± .003)
REF
0° – 6° TYP
GAUGE PLANE
1 2 3 4 5
0.53 ± 0.152
(.021 ± .006)
DETAIL “A”
0.86
(.034)
REF
1.10
(.043)
MAX
0.18
(.007)
SEATING
PLANE
0.17 – 0.27
(.007 – .011)
TYP
0.50
(.0197)
BSC
0.127 ± 0.076
(.005 ± .003)
MSOP (MS) 0603
NOTE:
1. DIMENSIONS IN MILLIMETER/(INCH)
2. DRAWING NOT TO SCALE
3. DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS.
MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
4. DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS.
INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
5. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.102mm (.004") MAX
sn430212 430212fs
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
19
LTC4302-1/LTC4302-2
U
TYPICAL APPLICATIO
2-WIRE SYSTEM 1
2-WIRE SYSTEM 2
VCC
VCC
C1
0.01µF
R1
10k
TO OTHER
SYSTEM 1
DEVICES
R2
10k
R3
8660Ω
SDA1
SCL1
R4
137Ω
VCC
LTC4302-1
SDAIN SDAOUT
SCLOUT
SCLIN
CONN
ADDRESS GPIO2
GPIO1
GND
IC1
C2
0.01µF
R5
10k
R6
10k
R7
5.1k
R8
5.1k
R9
10k
R10
10k
LONG DISTANCE
BUS
VCC
LTC4302-1
SDAOUT SDAIN
SCLOUT
SCLIN
CONN
GPIO2 ADDRESS
GPIO1
GND
IC2
R11
2000Ω
R13
10k
R14
10k
SDA2
SCL2
TO OTHER
SYSTEM 2
DEVICES
R12
1870Ω
4302 F16
Figure 16. Repeater/Bus Extender Application
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PART NUMBER
DESCRIPTION
COMMENTS
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SMBus Controlled CCFL Switching Regulator
1.25A, 200kHz, Floating or Grounded Lamp Configurations
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SMBus/I2C Fan Speed Controller in ThinSOTTM
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LTC1840
Dual I2C Fan Speed Controller
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LTC4300A-1/
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Provides Capacitance Buffering, SDA and SCL Hot Swapping,
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ThinSOT is a trademark of Linear Technology Corporation.
sn430212 430212fs
20
Linear Technology Corporation
LT/TP 1003 1K PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
 LINEAR TECHNOLOGY CORPORATION 2003