Car0812fp series rectifier, Data sheet, Input: 85v – GE Industrial Solutions CAR0812FP series User Manual

GE

Data Sheet

CAR0812FP series rectifier

Input: 85V

AC

to 264V

AC

; Output: 12V

DC

@ 850W; 3.3V

DC

or 5 V

DC

@ 1A

May 2, 2013

©2013 General Electric Company. All rights reserved.

Page 8

Digital Feature Descriptions

PMBus™ compliance:

The power supply is fully compliant

to the Power Management Bus (PMBus™) rev1.2
requirements.
Manufacturer specific commands located between

addresses 0xD0 to 0xEF provide instructions that either do
not exist in the general PMBus specification or make the
communication interface simpler and more efficient.

Master/Slave:

The ‘host controller’ is always the MASTER.

Power supplies are always SLAVES. SLAVES cannot initiate
communications or toggle the Clock. SLAVES also must
respond expeditiously at the command of the MASTER as
required by the clock pulses generated by the MASTER.

Clock stretching:

The ‘slave’ µController inside the power

supply may initiate clock stretching if it is busy and it desires
to delay the initiation of any further communications. During
the clock stretch the ‘slave’ may keep the clock LO until it is
ready to receive further instructions from the host controller.

The maximum clock stretch interval is 25ms.

The host controller needs to recognize this clock stretching,
and refrain from issuing the next clock signal, until the clock

line is released, or it needs to delay the next clock pulse
beyond the clock stretch interval of the power supply.

Note that clock stretching can only be performed after

completion of transmission of the 9

th

ACK bit, the exception

being the START command.

Figure 1. Example waveforms showing clock

stretching.

I

²C Bus Lock-Up detection:

The device will abort any

transaction and drop off the bus if it detects the bus being

held low for more than 35ms.

Communications speed:

Both 100kHz and 400kHz clock

rates are supported. The power supplies default to the
100kHz clock rate. The minimum clock speed specified by
SMBus is 10 kHz.

Packet Error Checking (PEC):

Although the power supply will

respond to commands with or without the trailing PEC, it is
highly recommended that PEC be used in all
communications. The integrity of communications is
compromised if packet error correction is not employed.
There are many functional features, including turning OFF
the main output, that should require validation to ensure
that the correct command is executed.

PEC is a CRC-8 error-checking byte, based on the polynomial
C(x) = x

8

+ x

2

+ x + 1, in compliance with PMBus™

requirements. The calculation is based in all message bytes,
including the originating write address and command bytes

preceding read instructions. The PEC is appended to the
message by the device that supplied the last byte.

SMBAlert#

:

The µC driven SMBAlert# signal informs the

‘master/host’ controller that either a STATE or ALARM
change has occurred. Normally this signal is HI. The signal
will change to its LO level if the power supply has changed
states and the signal will be latched LO until the power
supply either receives a ‘clear’ instruction as outlined below
or executes a READ STATUS_WORD. If the alarm state is still
present after the STATUS registers were reset, then the
signal will revert back into its LO state again and will latch

until a subsequent reset signal is received from the host
controller.

The signal will be triggered for any state change, including

the following conditions;



VIN under or over voltage



Vout under or over voltage



IOUT over current



Over Temperature warning or fault



Fan Failure



Communication error



PEC error



Invalid command



Internal faults

The power supply will clear the SMBusAlert# signal (release
the signal to its HI state) upon the following events:



Receiving a CLEAR_FAULTS command



The main output recycled (turned OFF and then ON) via
the ENABLE signal pin



The main output recycled (turned OFF and then ON) by
the OPERATION command



Execution of a READ of the STATUS_WORD register

Global broadcast:

This is a powerful command because it

can instruct all power supplies to respond simultaneously in
one command. But it does have a serious disadvantage.
Only a single power supply needs to pull down the ninth
acknowledge bit. To be certain that each power supply

responded to the global instruction, a READ instruction
should be executed to each power supply to verify that the
command properly executed. The GLOBAL BROADCAST

command should only be executed for write instructions to
slave devices.

Read back delay:

The power supply issues the SMBAlert #

notification as soon as the first state change occurred.

During an event a number of different states can be

transitioned to before the final event occurs. If a read back is
implemented rapidly by the host a successive SMBAlert#
could be triggered by the transitioning state of the power

supply. In order to avoid the triggering of successive
SMBAlert# s and thus reading a transitioning state, it is
prudent to wait more than 2 seconds after the receipt of an

SMBAlert# before executing a read back. This delay will
ensure that only the final state of the power supply is
captured.

Successive read backs:

Successive read backs to the power

supply should not be attempted at intervals faster than
every one second. This time interval is sufficient for the

Clock

Stretch