PCA9511AD,118 NXP Semiconductors, PCA9511AD,118 Datasheet - Page 5
PCA9511AD,118
Manufacturer Part Number
PCA9511AD,118
Description
IC HOTSWAP I2C/SMBUS BUFF 8SOIC
Manufacturer
NXP Semiconductors
Type
I²C-Bus and SMBus Switchr
Datasheet
1.PCA9511ADP118.pdf
(24 pages)
Specifications of PCA9511AD,118
Package / Case
8-SOIC (0.154", 3.90mm Width)
Applications
Hot-Swap/SMB Buffer
Internal Switch(s)
Yes
Current Limit
50mA
Voltage - Supply
2.7 V ~ 5.5 V
Operating Temperature
-40°C ~ 85°C
Mounting Type
Surface Mount
Supply Voltage (max)
5.5 V
Supply Voltage (min)
2.7 V
Maximum Operating Temperature
+ 85 C
Mounting Style
SMD/SMT
Minimum Operating Temperature
- 40 C
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Lead Free Status / RoHS Status
Lead free / RoHS Compliant, Lead free / RoHS Compliant
Other names
935279307118
PCA9511AD-T
PCA9511AD-T
PCA9511AD-T
PCA9511AD-T
NXP Semiconductors
PCA9511A_4
Product data sheet
8.2 Connect circuitry
8.3 Maximum number of devices in series
is activated during the initialization and is deactivated when the connection is made. The
precharge circuitry pulls up the SDA and SCL pins to 1 V through individual 100 k
nominal resistors. This precharges the pins to 1 V to minimize the worst case
disturbances that result from inserting a card into the backplane where the backplane and
the card are at opposite logic levels.
Once the connection circuitry is activated, the behavior of SDAIN and SDAOUT as well as
SCLIN and SCLOUT become identical with each acting as a bidirectional buffer that
isolates the input capacitance from the output bus capacitance while communicating the
logic levels. A LOW forced on either SDAIN or SDAOUT will cause the other pin to be
driven to a LOW by the part. The same is also true for the SCL pins. Noise between
0.7V
falls below 0.7V
one pin, the other pin in the pair turns on a pull-down driver that is referenced to a small
voltage above the falling pin. The driver will pull the pin down at a slew rate determined by
the driver and the load initially, because it does not start until the first falling pin is below
0.7V
down slew rate then the initial pull-down rate will continue. If the first falling pin has a slow
slew rate then the second pin will be pulled down at its initial slew rate only until it is just
above the first pin voltage then they will both continue down at the slew rate of the first.
Once both sides are LOW they will remain LOW until all the external drivers have stopped
driving LOWs. If both sides are being driven LOW to the same value for instance, 10 mV
by external drivers, which is the case for clock stretching and is typically the case for
acknowledge, and one side external driver stops driving that pin will rise until the internal
driver pulls it down to the offset voltage. When the last external driver stops driving a
LOW, that pin will rise up and settle out just above the other pin as both rise together with
a slew rate determined by the internal slew rate control and the RC time constant. As long
as the slew rate is at least 1.25 V/ s, when the pin voltage exceeds 0.6 V for the
PCA9511A, the rise time accelerator’s circuits are turned on and the pull-down driver is
turned off.
Each buffer adds about 0.1 V dynamic level offset at 25 C with the offset larger at higher
temperatures. Maximum offset (V
level at the signal origination end (master) is dependent upon the load and the only
specification point is that the I
although if lightly loaded the V
the level after four buffers would be 0.5 V, which is only about 0.1 V below the threshold of
the rising edge accelerator (about 0.6 V). With great care a system with four buffers may
work, but as the V
the rising edge accelerator thus introducing false clock edges. Generally it is
recommended to limit the number of buffers in series to two, and to keep the load light to
minimize the offset.
The PCA9510A (rise time accelerator is permanently disabled) and the PCA9512A (rise
time accelerator can be turned off) are a little different with the rise time accelerator turned
off because the rise time accelerator will not pull the node up, but the same logic that turns
CC
CC
. The first falling pin may have a fast or slow slew rate, if it is faster than the pull
and V
CC
CC
is generally ignored because a falling edge is only recognized when it
OL
with a slew rate of at least 1.25 V/ s. When a falling edge is seen on
moves up from 0.1 V, noise or bounces on the line will result in firing
Rev. 04 — 19 August 2009
2
OL
C-bus specification of 3 mA will produce V
may be ~0.1 V. Assuming V
offset
) is 0.150 V with a 10 k pull-up resistor. The LOW
Hot swappable I
2
C-bus and SMBus bus buffer
OL
= 0.1 V and V
PCA9511A
© NXP B.V. 2009. All rights reserved.
OL
< 0.4 V,
offset
= 0.1 V,
5 of 24
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