pca9512dp NXP Semiconductors, pca9512dp Datasheet - Page 5

pca9512dp

Manufacturer Part Number

pca9512dp

Description

Level Shifting Hot Swappable I2c And Smbus Buffer

Manufacturer

NXP Semiconductors

Datasheet

1.PCA9512DP.pdf (16 pages)

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Meier Automation Equipment Co., Limited

Part Number:

PCA9512DP

Manufacturer:

PHILIPS/飞利浦

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20 000

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Philips Semiconductors

Maximum number of devices in series

Each buffer adds about 0.065 V dynamic level offset at 25 C with

the offset larger at higher temperatures. Maximum offset (V

0.150 V. The LOW level at the signal origination end (master) is

dependent upon the load and the only specification point is the

lightly loaded the V

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

in firing the rising edge accelerator thus introducing false clock

edges. Generally it is recommended to limit the number of buffers in

series to two.

The PCA9510 (rise time accelerator is permanently disabled) and

the PCA9512 (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 on the accelerator turns the pull-down off. If the V

will not turn back on until a falling edge is detected; so if the noise is

small enough it may be possible to use more than two PCA9510 or

PCA9512 parts in series but is not recommended.

Consider a system with three buffers connected to a common node

and communication between the Master and Slave B that are

connected at either end of Buffer A and Buffer B in series as shown

in Figure 4. Consider if the V

the V

changing from Master to Slave B and then from Slave B to Master.

Before the direction change you would observe V

Buffer A of 0.3 V and its output, the common node, is 0.4 V. The

output of Buffer B and Buffer C would be 0.5 V, but Slave B is

driving 0.4 V, so the voltage at Slave B is 0.4 V. The output of

Buffer C is 0.5 V. When the Master pull-down turns off, the input of

Buffer A rises and so does its output, the common node, because it

2004 Oct 05

0.6 V and a rising edge is detected, the pull-down will turn off and

C-bus specification of 3 mA will produce V

Level shifting hot swappable I

= 0.1 V, the level after four buffers would be 0.5 V, which is only

MASTER

moves up from 0.1 V, noise or bounces on the line will result

of Slave B (when acknowledging) is 0.4 V with the direction

buffer A

may be 0.1 V. Assuming V

common

Figure 4.

node

at the input of Buffer A is 0.3 V and

buffer B

buffer C

< 0.4 V, although if

SLAVE B

SLAVE C

SW02353

at the input of

= 0.1 V and

C and SMBus buffer

is above

) is

is the only part driving the node. The common node will rise to 0.5 V

before Buffer B’s output turns on, if the pull-up is strong the node will

bounce. If the bounce goes above the threshold for the rising edge

accelerator 0.6 V the accelerators on both Buffer A and Buffer C

will fire contending with the output of Buffer B. The node on the input

of Buffer A will go HIGH as will the input node of Buffer C. After the

common node voltage is stable for a while the rising edge

accelerators will turn off and the common node will return to 0.5 V

because the Buffer B is still on. The voltage at both the Master and

Slave C nodes would then fall to 0.6 V until Slave B turned off. This

would not cause a failure on the data line as long as the return to

0.5 V on the common node ( 0.6 V at the Master and Slave C)

occurred before the data setup time. If this were the SCL line, the

parts on Buffer A and Buffer C would see a false clock rather than a

stretched clock, which would cause a system error.

Propagation Delays

The delay for a rising edge is determined by the combined pull-up

current from the bus resistors and the PCA9512 and the effective

capacitance on the lines. If the pull-up currents are the same, any

difference in capacitance between the two sides. The t

negative if the output capacitance is less than the input capacitance

and would be positive if the output capacitance is larger than the

input capacitance, when the currents are the same.

The t

fall until the input is below 0.7V

SCLOUT) and the output pull down turn on has a nonzero delay,

and the output has a limited maximum slew rate and even it the

input slew rate is slow enough that the output catches up it will still

lag the falling voltage of the input by the offset voltage, The

maximum t

and the output is still limited by its turn on delay and the falling edge

slew rate, The output falling edge slew rate (which is a function of

temperature, V

load capacitance.

Rise Time Accelerators

During positive bus transitions a 2 mA current source is switched on

to quickly slew the SDA and SCL lines HIGH once the input level of

0.6 V is exceeded. The rising edge rate should be at least 1.25 V/ s

to guarantee turn on of the accelerators.

ACC Boost Current Enable

Users having lightly loaded systems may wish to disable the

rise-time accelerators. Driving this pin to ground turns off the

rise-time accelerators on all four SDA and SCL pins. Driving this pin

to the V

accelerators.

PHL

CC2

can never be negative because the output does not start to

PHL

voltage enables normal operation of the rise-time

occurs when the input is driven LOW with zero delay

or V

CC2

, and process) as well as load current and

(or 0.7V

CC2

for SDAOUT and

PCA9512

Product data sheet

PLH

may be

pca9512dp NXP Semiconductors, pca9512dp Datasheet - Page 5

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