GE Data Sheet
April 23, 2013 ©2013 General Electric Company. All rights reserved.
CAR2512FP Front-End
Input: 90VAC to 264VAC; Output: 12VDC @ 2500W; 3.3VDC or 5 VDC @ 1A
Features
Universal input with PFC
Constant power characteristic
2 front panel LEDs: 1-input;2-[output, fault, over temp]
Remote ON/OFF control of the 12VDC output
Remote sense on the 12VDC output
No minimum load requirements
Active load sharing (single wire)
Hot Plug-ability
Efficiency: typically 92.5% @ 50% load
and 90.0% @ 20% load
Standby orderable either as 3.3VDC or 5VDC
Auto recoverable OC & OT protection
Operating temperature: -10 - 70C (de-rated above 50C)
Digital status & control: I2C and PMBus serial bus
EN/IEC/UL60950-1 2nd edition; UL, CSA and VDE
EMI: class A FCC docket 20780 part 15, EN55022
Meets EN6100 immunity and transient standards
Shock & vibration: NEBS GR-63-CORE, level 3
Applications
12VDC distributed power architectures
Datacom, Telecom and ATE Equipment
Mid to high-end Servers
Enterprise Networking
Network Attached Storage
Routers/Switches/Access Nodes
Broadband Switches
Description
The CAR2512FP Front-End provides highly efficient isolated power from worldwide input mains in a compact 1U
industry standard form factor in an unprecedented power density of 25W/in3. It is ideal for datacom applications
such as enterprise networking, mid to high-end servers, and storage equipment, where mid to light load efficiency is
of key importance given the nature of the power consumption of the end application.
The high-density, front-to-back airflow is designed for minimal space utilization and is highly expandable for future
growth. The industry standard PMBus compliant I2C communications buss offers a full range of control and
monitoring capabilities. The SMBAlert signal pin alerts customers automatically of any state change within the power
supply.
* UL is a registered trademark of Underwriters Laboratories, Inc.
CSA is a registered trademark of Canadian Standards Association.
VDE is a trademark of Verband Deutscher Elektrotechniker e.V.
§ Intended for integration into end-user equipment. All the required procedures for CE marking of end-user equipment should be followed. (The CE mark is placed on selected products.)
** ISO is a registered trademark of the International Organization of Standards.
+ PMBus name and logo are registered trademarks of the System Management Interface Forum (SMIF)
RoHS Compliant
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 2
Absolute Maximum Ratings
Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. These are absolute stress ratings only, functional
operation of the device is not implied at these or any other conditions in excess of those given in the operations sections of the data sheet. Exposure
to absolute maximum ratings for extended periods can adversely affect the device reliability.
Parameter Symbol Min Max Unit
Input Voltage: Continuous VIN 0 264 VAC
Operating Ambient Temperature TA -10 701 °C
Storage Temperature TSTG -40 85 °C
I/O Isolation voltage to Frame (100% factory Hi-Pot tested) 1500 VAC
Electrical Specifications
Unless otherwise indicated, specifications apply over all operating input voltage, load, and temperature conditions.
INPUT
Parameter Symbol Min Typ Max Unit
Operational Range VIN 90 110/230 264 VAC
Frequency Range (ETSI 300-132-1 recommendation) FIN 47 50/60 63 Hz
Main Output Turn_OFF VIN 80 VAC
Maximum Input Current (VOUT= VO, set, IOUT=IO, max) VIN= 100VAC IIN
14.3
16 AAC
VIN= 180VAC
Cold Start Inrush Current IIN 40 APEAK
(Excluding x-caps, 25C, <10ms, per ETSI 300-132)
Efficiency (TAMB=25C, VIN = 230V, VOUT= 12V, IO, max), 100% load
91.6
92.5
90.0
%
50% load
20% load
Power Factor (VIN=230VAC, IOUT=IO, max) PF 0.99
Holdup time2 (VOUT 10.8VDC, Tamb 25C, IOUT=IO, max) VIN= 230VAC
VIN= 100VAC T 12
15 ms
Early warning prior to output falling below regulation 2 ms
Ride through, high line
T 10 ms
Leakage Current (VIN= 250VAC, Fin = 60Hz) IIN 3 mArms
Isolation Input/Output
3000 VAC
Input/Frame 1500 VAC
Output/Frame 100 VDC
12VDC MAIN OUTPUT
Parameter Symbol Min Typ Max Unit
Output Power HL / LL [180 – 264 / 90-132 VAC] VDC 12VDC W 0 - 2500/1200 W
VDC 12VDC 0 - 2246/1078 W
Set point
VOUT
11.9 12.00 12.1 VDC
Overall regulation (load, temperature) -2 +2 %
Ripple and noise3 -120 +120 mVp-p
Turn-ON overshoot +3 %
Turn-ON delay T 2 sec
1 Derated above 50C at 2.5%/C
2 12V output can decay down to 10.8V
3 Measured across a 10µf electrolytic and a 0.1µf ceramic capacitors in parallel. 20MHz bandwidth
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 3
12VDC MAIN OUTPUT (continued)
Parameter Symbol Min Typ Max Unit
Remote ON/OFF delay time 40 ms
Turn-ON rise time (10 – 90% of VOUT) 50 ms
Transient response 50% step [10%-60%, 50% - 100%]
(dI/dt – 1A/µs, recovery 300µs)
VOUT
-5 +5 %VOUT
Programmable range (hardware & software) 10.8 13.2 VDC
Overvoltage protection, latched
(recovery by cycling OFF/ON via hardware or software) 13.8 14.8 15.8 VDC
Output current [V VIN = HL
VIN = LL IOUT
0
208
100 ADC
Current limit, Hiccup (programmable level) 110 130 % of FL
Active current share -5 +5 % of FL
STANDBY OUTPUT
Parameter Symbol Min Typ Max Unit
Set point VOUT 3.3 / 5.0 VDC
Overall regulation (load, temperature, aging) VOUT -5 +5 %
Ripple and noise 50 mVp-p
Output current IOUT 0 1 ADC
Isolation Output/Frame 100 VDC
General Specifications
Parameter Min Typ Max Units Notes
Reliability 400,000
Hrs
Full load, 25C ; MTBF per SR232 Reliability
protection for electronic equipment, method I,
case III,
Service Life 10 Yrs Full load, excluding fans
Weight
Kgs
(Lbs)
Feature Specifications
Unless otherwise indicated, specifications apply over all operating input voltage, resistive load, and temperature conditions. See
Feature Descriptions for additional information.
Parameter Symbol Min Typ Max Unit
Remote ON/OFF (Needs to be pulled HI via an external resistor)
Logic High (Module ON) IIH 20 µA
V
IH 0.7VDD 12 VDC
Logic Low (Module OFF) IIL 1 mA
V
IL 0 0.8 VDC
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 4
Feature Specifications (continued)
Parameter Symbol Min Typ Max Unit
Output Voltage programming (Vprog)
Equation: Vout = 10.8 + (Vprog * 0.96)
Vprog range Vprog 0 2.5 VDC
Programmed output voltage range Vo 10.8 13.2 VDC
Voltage adjustment resolution (8-bit A/D) Vo 10 mVDC
Output configured to 13.2VDC V
prog 2.5 3.0 VDC
Output configured to the 12VDC set-point Vprog 3.0 VDC
Enable [short pin controlling presence of the 12VDC output]
12V output OFF VI 0.7VDD 12 VDC
12V output ON VI 0 0.8 VDC
Write protect (Wp)
Write protect enabled VI 0.7VDD 12 VDC
Write
p
rotect disabled VI
0
0.8 VDC
INPUT(AC)-OK (Needs to be pulled HI via an external resistor)
Logic High (Input within normal range; VIN 80VAC) IOH 20 µA
V
OH 0.7VDD 12 VDC
Logic Low (Input out of range; VIN 75VAC) IOL 20 mA
V
OL 0 0.4 VDC
DC-OK ( Internally connected to 3.3V via a 10k resistor)
Logic High (Output voltage is present; VOUT 10.7VDC) IOH 20 µA
V
OH 0.7VDD 12 VDC
Logic Low (Output voltage is not present; VOUT 10.2VDC ) IOL 20 mA
V
OL 0 0.4 VDC
Over Temperature Warning (Needs to be pulled HI via an external
it )
Logic High (temperature within normal range) IOH 20 µA
VOH 0.7VDD 12 VDC
Logic Low (temperature is too high) IOL 20 mA
V
OL 0 0.4 VDC
Delayed shutdown after Logic Low transition Tdelay 10 sec
Fault (Needs to be pulled HI via an external resistor)
Logic High (No fault is present) IOH 20 µA
V
OH 0.7VDD 12 VDC
Logic Low (Fault is present) IOL 20 mA
V
OL 0 0.4 VDC
PS Present (Needs to be pulled HI via an external resistor)
Logic High (Power supply is not plugged in)
Logic Low (Power supply is present) VIL 0 0.1 VDC
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 5
Feature Specifications (continued)
Parameter Symbol Min Typ Max Unit
SMBAlert# (Interrupt) (Needs to be pulled HI via an external
it
)
Logic High (No Alert - normal) IOH 20 µA
V
OH 0.7VDD 12 VDC
Logic Low (Alert is set) IOL 20 mA
V
OL 0 0.4 VDC
Output current monitor (Imon)
Resolution 15 mV/A
Measurement range IO 0 208 ADC
Measurement accuracy, load > 25% of FL -10 +10 %
Analog output range Vmon 0 3.3 VDC
Sourced output current IO 5 mADC
Digital Interface Specifications
Parameter Conditions Symbol Min Typ Max Unit
PMBus Signal Interface Characteristics
Input Logic High Voltage (CLK, DATA) VIH 2.1 3.6 VDC
Input Logic Low Voltage (CLK, DATA) VIL 0 0.8 VDC
Input high sourced current (CLK, DATA) IIH 0 10 μA
Output Low sink Voltage (CLK, DATA, SMBALERT#) IOUT=3.5mA VOL 0.4 VDC
Output Low sink current (CLK, DATA, SMBALERT#) IOL 3.5 mA
Output High open drain leakage current
(CLK,DATA, SMBALERT#) VOUT=3.6V IOH 0 10 μA
PMBus Operating frequency range Slave Mode FPMB 10 400 kHz
Measurement System Characteristics (all measurement tolerances are typical estimations under normal operating conditions)
Clock stretching tSTRETCH 25 ms
IOUT measurement range Linear IRNG 0 208 ADC
IOUT measurement accuracy 25°C IACC -3 +3 % of FL
VOUT measurement range Linear VOUT(rng) 0 14 VDC
VOUT measurement accuracy VOUT(acc) -3 +3 %
Temp measurement range Linear Temp(rng) 0 120 C
Temp measurement accuracy4 Temp(acc) -5 +5 C
IIN measurement range Linear IIN(rng) 0 40 AAC
IIN measurement accuracy IIN(acc) -5 +5 %
VIN measurement range Linear VIN(rng) 0 264 VAC
VIN measurement accuracy VIN(acc) -3 +3 %
PIN measurement range Linear PN(rng) 0 3000 W
PIN measurement accuracy PIN(acc) -5 +5 %
Fan Speed measurement range Linear 0 30k RPM
Fan Speed measurement accuracy -5 5 %
Fan speed control range -direct- 0 100 %
4 Temperature accuracy reduces non-linearly with decreasing temperature
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 6
Environmental Specifications
Parameter Min Typ Max Units Notes
Ambient Temperature -105 70 °C
Derated above 50C
Storage Temperature -40 85 °C
Operating Altitude 2250/7382 m/ft
Non-operating Altitude 8200/30k m / ft
Power Derating with Temperature 2.5 %/°C 50C to 70C
Power Derating with Altitude 2.0 C/301 m
C/1000 ft
Above 2250 m/7382 ft
Acoustic noise 55 dbA Full load
Over Temperature Protection 125/110 °C Shutdown / restart
Humidity
Operating
Storage
30
10
95
95
% Relative humidity, non-condensing
Shock and Vibration acceleration 6 Grms
NEBS GR-63-CORE, Level 3, 20 -
2000Hz, min 30 minutes
Earthquake Rating
4
Zone
NEBS GR-63-CORE, all floors, Seismic
Zone 4 Designed and tested to meet
NEBS specifications.
EMC Compliance
Parameter Criteria Standard Level Test
AC input
Conducted emissions EN55022, FCC Docket 20780 part 15, subpart J
EN61000-3-2
A* 0.15 30MHz
0 – 2 KHz
Radiated emissions** EN55022 A* 30 – 10000MHz
AC input
immunity
Voltage dips EN61000-4-11 B -30%, 10ms
B -60%, 100ms
B -100%, 5sec
Voltage surge EN61000-4-5 A 4kV, 1.2/50µs, common mode
A 2kV, 1.2/50µs, differential mode
Fast transients EN61000-4-4 B 5/50ns, 2kV (common mode)
Enclosure
immunity
Conducted RF fields EN61000-4-6 A 130dBµV, 0.15-80MHz, 80% AM
Radiated RF fields EN61000-4-3 A 10V/m, 80-1000MHz, 80% AM
ENV 50140 A
ESD EN61000-4-2 B 4kV contact, 8kV air
* Note: Contact the factory for a recommended external EMI filter to meet Class B emissions
** Radiated emissions compliance is contingent upon the final system configuration.
5 Designed to start at an ambient down to -40°C; meet spec after 30 min warm up period, may not meet operational limits below -10°C.
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 208A; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 7
Control and Status
Control hierarchy: Some features, such as output voltage,
can be controlled both through hardware and firmware. For
example, the output voltage is controlled both by the signal pin
(Vprog) and the PMBus command, (Vout_command) .
Using output voltage as an example; the Vprog signal pin has
ultimate control of the output voltage until the Vprog is either >
3VDC or a no connect. When the programming signal via Vprog
is either a no connect or > 3VDC, it is ignored, the output
voltage is set at its nominal 12VDC and the unit output voltage
can be controlled via the PMBus command, (Vout_command).
Analog controls: Details of analog controls are provided in
this data sheet under Signal Definitions.
Common ground: All signals and outputs are referenced to
Output return. These include ‘VSTDBY return’ and ‘Signal return’.
Control Signals
Voltage programming (Vprog): An analog voltage on this
signal can vary the output voltage ± 10% of nominal, from
10.8VDC to 13.2VDC. The equation of this signal is:
VOUT = 10.8 (Vprog * 0.96) where Vprog = 0 to 2.5VDC
Between 2.5 and 3V the output stays at 13.2VDC. If Vprog is >
3V, or left open, the programming signal is ignored and the
unit output is set at the setpoint of 12VDC.
Load share (Ishare): This is a single wire analog signal that is
generated and acted upon automatically by power supplies
connected in parallel. The Ishare pins should be tied together
for power supplies if active current share among the power
supplies is desired. No resistors or capacitors should get
connected to this pin.
Remote_ON/OFF: Controls presence of the 12VDC output
voltage. This is an open collector, TTL level control signal that
needs to be pulled HI externally through a resistor.
A turn OFF command either through this signal (Remote
ON/OFF) or firmware commanded would turn OFF the 12V
output.
Enable: This is a short signal pin that controls the presence of
the 12VDC main output. This pin should be connected to ‘output
return’ on the system side of the output connector. The
purpose of this pin is to ensure that the output turns ON after
engagement of the power blades and turns OFF prior to
disengagement of the power blades.
Write protect (WP): This signal protects the contents of the
EEPROM from accidental over writing. When left open the
EEPROM is write protected. A LO (TTL compatible) permits
writing to the EEPROM. This signal is pulled HI internally by the
power supply.
Status Signals
Output current monitor (Imon): A voltage level proportional to
the delivered output current is present on this pin. The signal
level is 0.04V per amp ± 0.25V.
Input_OK: A TTL compatible status signal representing
whether the input voltage is within the anticipated range. This
signal needs to be pulled HI externally through a resistor.
DC_OK: A TTL compatible status signal representing whether
the output voltage is present. This signal needs to be pulled HI
externally through a resistor.
Over_temp_warning: A TTL compatible status signal
representing whether an over temperature exists. This signal
needs to be pulled HI externally through a resistor.
If an over temperature should occur, this signal would pull LO
approximately 10 seconds prior to shutting down the power
supply. The unit would restart if internal temperatures recover
within normal operational levels. At that time the signal reverts
back to its open collector (HI) state.
Fault: A TTL compatible status signal representing whether a
Fault occurred. This signal needs to be pulled HI externally
through a resistor.
This signal activates for OTP, OVP, OCP, INPUT fault or No
output.
PS_Present: This pin is connected to ‘output return’ within the
power supply. Its intent is to indicate to the system that a
power supply is present. This signal may need to be pulled HI
externally through a resistor.
Interrupt (SMBAlert#): A TTL compatible status signal,
representing the SMBusAlert# feature of the PMBus compatible
i2C protocol in the power supply. This signal needs to be pulled
HI externally through a resistor.
Serial Bus Communications
The I²C interface facilitates the monitoring and control of
various operating parameters within the unit and transmits
these on demand over an industry standard I²C Serial bus.
All signals are referenced to ‘Signal Return’.
Device addressing: The microcontroller (MCU) and the EEPROM
have the following addresses:
Device
Address
Address Bit Assignments
(Most to Least Significant)
MCU 0xBx 1 0 1 1 A2 A1 A0 R/W
Broadcast 0x00 0 0 0 0 0 0 0 0
EEPROM 0xAx 1 0 1 0 A2 A1 A0 R/W
The Global Broadcast instruction executes a simultaneous
write instruction to all power supplies. A read instruction
cannot be accessed globally. The three programmable address
bits are the same for all I2C accessible devices within the
power supply.
Address lines (A2, A1, A0): These signal pins allow up to eight
(8) modules to be addressed on a single I²C bus. The pins are
pulled HI internal to the power supply. For a logic LO these pins
should be connected to ‘Output Return’
Serial Clock (SCL): The clock pulses on this line are generated
by the host that initiates communications across the I²C Serial
bus. This signal is pulled up internally to 3.3V by a 10k
resistor. The end user should add additional pull up resistance
as necessary to ensure that rise and fall time timing and the
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 8
maximum sink current is in compliance to the I²C
specifications.
Serial Data (SDA): This line is a bi-directional data line. . This
signal is pulled up internally to 3.3V by a 10k resistor. The end
user should add additional pull up resistance as necessary to
ensure that rise and fall time timing and the maximum sink
current is in compliance to the I²C specifications.
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 9th ACK bit, the exception
being the START command.
Figure 1. Example waveforms showing clock stretching.
I²C 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) = x8 + x2 + 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
Detected 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
successive SMBAlert# s and read back and also to avoid
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
Clock
Stretch
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 9
one second. This time interval is sufficient for the internal
processors to update their data base so that successive reads
provide fresh data.
PMBusTM Commands
Standard instruction: Up to two bytes of data may follow an
instruction depending on the required data content. Analog
data is always transmitted as LSB followed by MSB. PEC is
optional and includes the address and data fields.
1 8 1 8 1
S Slave address Wr A Command Code A
8 1 8 1 8 1 1
Low data byte A High data byte A PEC A P
Master to Slave Slave to Master
SMBUS annotations; S – Start , Wr – Write, Sr – re-Start, Rd –
Read,
A – Acknowledge, NA – not-acknowledged, P – Stop
Standard READ: Up to two bytes of data may follow a READ
request depending on the required data content. Analog data
is always transmitted as LSB followed by MSB. PEC is
mandatory and includes the address and data fields. PEC is
optional and includes the address and data fields.
1 7 1 1 8 1
S Slave address Wr A Command Code A
1 7 1 1 8 1
Sr Slave Address Rd A LSB A
8 1 8 1 1
MSB A PEC No-ack P
Block communications: When writing or reading more than
two bytes of data at a time BLOCK instructions for WRITE and
READ commands must be used instead of the Standard
Instructions Error! Reference source not found. write any
number of bytes greater than two.
Block write format:
1 7 1 1 8 1
S Slave address Wr A Command Code A
8 1 8 1 8 1
Byte count = N A Data 1 A Data 2 A
8 1 8 1 8 1 1
………. A Data 48 A PEC A P
Block read format:
1
7 1 1 8 1
S
Slave address Wr A Command Code A
1 7 1 1
Sr Slave Address Rd A
8 1 8 1 8 1
Byte count = N A Data 1 A Data 2 A
8 1 8 1 8 1 1
………. A Data 48 A PEC NoAck
P
Linear Data Format The definition is identical to Part II of the
PMBus Specification. All standard PMBus values, with the
exception of output voltage related functions, are represented
by the linear format described below. Output voltage functions
are represented by a 16 bit mantissa. Output voltage has a E=9
constant exponent.
The Linear Data Format is a two byte value with an 11-bit,
two’s complement mantissa and a 5-bit, two’s complement
exponent or scaling factor, its format is shown below.
Data Byte High Data Byte Low
Bit
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
Exponent (E) Mantissa (M)
The relationship between the Mantissa, Exponent, and Actual
Value (V) is given by the following equation:
E
MV 2
Where: V is the value, M is the 11-bit, two’s omplement
mantissa, E is the 5-bit, two’s complement exponent
PMBusTM Command set:
Command
Hex
Code
Data
Byte Function
Operation 01 1 Output ON/OFF
ON_OFF_config 02 1 09, output ON default
Clear_faults 03 0 Clear Status
Write_protect 10 1 Write control
Store_default_all 11 0 Store permanently
Restore_default_all 12 0 Reset defaults
Capability 19 1 30h, 400kHz, SMBAlert
Vout_mode 20 1 Vout constants
Vout_command 21 2 Set Vout
Fan_command_1 3B 2 Set fan speed in RPM
Vout_OV_fault_limit 40 2 Set OV fault limit
Vout_OV_fault_response 41 1
Vout_OV_warn_limit 42 2 Set OV warn limit
Vout_UV_warn_limit 43 2 Set UV warn limit
Vout_UV_fault_limit 44 2
Vout_UV_fault_response 45 1
Iout_OC_fault_limit 46 2
Iout_OC_fault_response 47 1
Latch or hiccup
Iout_OC_warn_limit 4A 2
Set OC warn limit
OT_fault_limit 4F 2
OT_fault_response 50 1
Latch or hiccup
OT_warn_limit 51 2
Set OT warn limit
UT_warn_limit 52 2
UT_fault_limit 53 2
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 10
Command
Hex
Code
Data
Field Function
UT_fault_response 54 1
Vin_OV_fault_limit 55 2
Vin_OV_warn_limit 57 2
Set OV warn limit
Vin_UV_warn_limit 58 2 Set UV warn limit
Vin_UV_fault_limit 59 2 Set UV shutdown
Status_byte 78 1
Status_word 79 2
Status_Vout 7A 1
Status_Iout 7B 1
Status_input 7C 1
Status_temperature 7D 1
Status_CML 7E 1
Status_other 7F 1
Status_mfr_specific 80 1
Status_fan_1_2 81 1
Read_Vin 88 2 Read input voltage
Read Iin 89 2 Read input current
Read_Vout 8B 2 Read output voltage
Read_Iout 8C 2 Read output current
Read_temperature 8D 2 Read Temperature
Read_fan_speed_1 90 2 In RPM
Read_fan_speed_2 91 2 In RPM
Read_Pout 96 2
Read_Pin 97 2
PMBus revision 98 1
Mfr_ID 99 5 FRU_ID
Mfr_model 9A 15
Mfr_revision 9B 4
Mfr_location 9C 4
Mfr_date 9D 6
Mfr_serial 9E 15
Mfr_Vin_min A0 2
Mfr_Vin_max A1 2
Mfr_Iin_max A2 2
Mfr_Pin_max A3 2
Mfr_Vout_min A4 2
Mfr_Vout_max A5 2
Mfr_Iout_max A6 2
Mfr_Pout_max A7 2
Mfr_Tambient_max A8 2
Mfr_Tambient_min A9 2
User_data_00 B0 48
User memory space
User_data_01 B1 48
User memory space
FRW_revision D0 1
Ilimit_control_I2C D3 2
Ilimit set (1/100A)
Vout_control_ I2C D4 2
Vout set (1/512V)
Fan_duty_cycle D6 1
Duty_cycle in %
Fan_speed D7 1
Control in duty cycle
Vprog_ext D8 2
Read_Vout_ I2C E0 2 1/512V
Read_Iout_ I2C E1 2 1/100A
Read_TS_ I2C E2 2
Heat sink temp C
CMD_OFF_ I2C E3 2 01-OFF, 00-ON
OTF_limit_ I2C E4 2
OT fault limit C
OTF_recovery_ I2C E5 2
OT fault recovery C
DCOKHI_ I2C E6 2 High OV fault (1/512V)
DCOKLO_ I2C E7 2 Low OV fault (1/512V)
Fan1_speed_ I2C E9 2 RPM
Command
Hex
Code
Data
Field Function
Fan2_speed_ I2C EA 2 RPM
Read_Vin_ I2C ED 2 Vin (1/100V)
Read_Iin_ I2C EE 2 Iin (1/100A)
Read_Pin_ I2C EF 2
Status Register Bit Allocation:
Register
Code
Bit Function
Status_Byte 78
7 Busy
6 DC_ OFF
5 Output OV Fault detected
4 Output OC Fault detected
3 Input UV Fault detected
2 Temperature Fault/warning
detected
1 CML (communication fault)
detected
0 None of Below
Status_word
(includes Status_byte) 79
7 OV Fault/Warning detected
6 OC Fault/Warning detected
5 Input Fault/Warning detected
4 Mfr_specific register change
detected
3 DC_OFF
2 Fan Fault or Warning
detected
1 Other fault
0 Unknown
Status_Vout 7A
7 Vout OV Fault
6 Vout OV Warning
5 Vout UV Warning
4 Vout UV Fault
3 N/A
2 N/A
1 N/A
0 N/A
Status_Iout 7B
7 IOUT OC Fault
6 N/A
5 IOUT OC Warning
4 N/A
3 N/A
2 N/A
1 N/A
0 N/A
Status_input 7C
7 Vin OV Fault
6 Vin OV Warning
5 Vin UV Warning
4 Vin UV Fault
3 N/A
2 N/A
1 N/A
0 N/A
Status_temperature 7D
7 OT Fault
6 OT Warning
5 N/A
4 N/A
3 N/A
2 N/A
1 N/A
0 N /A
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 11
Register Code Bit Function
Status_cml 7E
7 Invalid/Unsupported
Command
6 Invalid/Unsupported Data
5 Packet Error Check Failed
4 Memory Fault Detected
3 Processor Fault Detected
2 Reserved
1 Other Communications Fault
0 Other Memory or Logic Fault
Status_fan_1_2 81
7 Fan 1 Fault
6 Fan 2 Fault
5 N/A
4 N/A
3 Fan 1 Speed Overridden
2 Fan 2 Speed Overridden
1 N/A
0 N/A
Status_mfr_specif
ic 80
7 3.3V_fault
6 N/A
5 Interrupt
4 Fault detected
3 PS_remote_OFF
2 DC_fault
1 INPUT_fault
0 0 – AC high line,
1 – AC low line
Command Descriptions
Operation (01) : By default the Power supply is turned ON at
power up as long as Power ON/OFF signal pin is active HI. The
Operation command is used to turn the Power Supply ON or
OFF via the PMBus. The data byte below follows the
OPERATION command.
FUNCTION DATA BYTE
Unit ON 80
Unit OFF 00
To RESET the power supply cycle the power supply OFF, wait at
least 2 seconds, and then turn back ON. All alarms and
shutdowns are cleared during a restart.
Clear_faults (03): This command clears all STATUS and FAULT
registers and resets the SMBAlert# line.
If a fault still persists after the issuance of the clear_faults
command the specific registers indicating the fault are reset
and the SMBAlert# line is activated again.
WRITE_PROTECT register (10): Used to control writing to the
PMBus device. The intent of this command is to provide
protection against accidental changes. All supported
command parameters may have their parameters read,
regardless of the write_protect settings. The contents of this
register can be stored to non-volatile memory using the
Store_default_code command. The default setting of this
register is disable_all_writes except write_protect 0x80h.
FUNCTION DATA BYTE
Enable all writes 00
Disable all writes except write_protect 80
Disable all writes except write_protect and
OPERATION
40
Vout_Command (21) : This command is used to change the
output voltage of the power supply. Changing the output
voltage should be performed simultaneously to all power
supplies operating in parallel using the Global Address
(Broadcast) feature. If only a single power supply is instructed
to change its output, it may attempt to source all the required
power which can cause either a power limit or shutdown
condition.
Software programming of output voltage permanently
overrides the set point voltage configured by the Vprog signal
pin. The program no longer looks at the ‘Vprog pin’ and will not
respond to any hardware voltage settings. If power is removed
from the µController it will reset itself into its default
configuration looking at the Vprog signal for output voltage
control. In many applications, the Vprog pin is used for setting
initial conditions, if different that the factory setting. Software
programming then takes over once I2C communications are
established.
To properly hot-plug a power supply into a live backplane, the
system generated voltage should get re-configured into either
the factory adjusted firmware level or the voltage level
reconfigured by the margin pin. Otherwise, the voltage state
of the plugged in power supply could be significantly different
than the powered system.
Vout_OV_warn_limit (42): OV_warning is extremely useful
because it gives the system controller a heads up that the
output voltage is drifting out of regulation and the power
supply is close to shutting down. Pre-amative action may be
taken before the power supply would shut down and
potentially disable the system.
OC and OT_fault_ response (47, 50): The default response for
both OC and OT is auto_restart (hiccup). Each register,
individually, can be reconfigured into a latched state. Latched
and hiccup are the only supported states.
Restart after a latch off: Either of four restart possibilities are
available. The hardware pin Remote ON/OFF may be turned
OFF and then ON. The unit may be commanded to restart via
i2c through the Operation command by first turning OFF then
turning ON . The third way to restart is to remove and reinsert
the unit. The fourth way is to turn OFF and then turn ON ac
power to the unit. The fifth way is by changing firmware from
latch off to restart. Each of these commands must keep the
power supply in the OFF state for at least 2 seconds, with the
exception of changing to restart.
A power system that is comprised of a number of power
supplies could have difficulty restarting after a shutdown event
because of the non-synchronized behavior of the individual
power supplies. Implementing the latch-off mechanism
permits a synchronized restart that guarantees the
simultaneous restart of the entire system.
A synchronous restart can be implemented by;
1. Issuing a GLOBAL OFF and then ON command to all power
supplies,
2. Toggling Off and then ON the Remote ON/OFF signal
3. Removing and reapplying input commercial power to the
entire system.
The power supplies should be turned OFF for at least 20 – 30
seconds in order to discharge all internal bias supplies and
reset the soft start circuitry of the individual power supplies.
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 12
Auto_restart: Auto-restart is the default configuration for
recovering from over-current and over-temperature
shutdowns.
An overvoltage shutdown is followed by three attempted
restarts, each restart delayed 1 second, within a 1 minute
window. If within the 1 minute window three attempted
restarts failed, the unit will latch OFF. If less than 3 shutdowns
occur within the 1 minute window then the count for latch OFF
resets and the 1 minute window starts all over again.
Vin_UV_warn_limit (58): This is another warning flag
indicating that the input voltage is decreasing dangerously
close to the low input voltage shutdown level.
Status_word (79): returns two bytes of information. The upper
byte bit functionality is tabulated in the Status_word section.
The lower byte bit functionality is identical to Status_byte.
Fan_speed (D7): This register can be used to ‘read’ the fan
speed in adjustment percent (0 – 100%) or set the fan speed in
adjustment percent (0 – 100%). The speed of the fan cannot
be reduced below what the power supply requires for its
operation. The register value is the percent number, it is not in
linear format.
Invalid commands or data: The power supply notifies the
MASTER if a non-supported command has been sent or invalid
data has been received. Notification is implemented by setting
the appropriate STATUS and ALARM registers and setting the
SMBAlert# flag.
If a non-supported read is requested the power supply will
return all 0x00h.
Restart after a lachoff: To restart after a latch_off either of
four restart mechanisms are available. The hardware pin
Remote ON/OFF may be turned OFF and then ON. The unit
may be commanded to restart via i2c through the Operation
command by first turning OFF then turning ON . The third way
to restart is to remove and reinsert the unit. The fourth way is
to turn OFF and then turn ON ac power to the unit. The fifth
way is by changing firmware from latch off to restart. Each of
these commands must keep the power supply in the OFF state
for at least 2 seconds, with the exception of changing to
restart.
A successful restart shall clear all alarm registers.
A power system that is comprised of a number of power
supplies could have difficulty restarting after a shutdown event
because of the non-synchronized behavior of the individual
power supplies. Implementing the latch-off mechanism
permits a synchronized restart that guarantees the
simultaneous restart of the entire system.
A synchronous restart can be implemented by;
1. Issuing a GLOBAL OFF and then ON command to all power
supplies,
2. Toggling Off and then ON the Remote ON/OFF signal
3. Removing and reapplying input commercial power to the
entire system.
It is good practice to turn OFF the power supplies for about 20
– 30 seconds in order to discharge all internal bias supplies
and reset the soft start circuitry of the individual power
supplies.
Control and Read accuracy:
The estimates below are believed to be reasonable under most
operating conditions. However, these are typical numbers and
not hard bound values that cannot be exceeded. In most
nominal operating conditions the returned values are
significantly better than these estimates.
FUNCTION
ACCURACY
Vout_command ± 2%
Vout_OV_fault_limit ± 3%
Iout_OC_warn_limit ± 4% of FL
OT_warn_limit ± 5C
Vin_UV_warn_limit ± 3%
Vin_UV_fault_limit ± 3%
Read_Vin ± 3%
Read_Vout ± 2%
Read_Iout ± 4% of FL
Read_temperature ± 5C
Read_Pin ±10%
Read_Pout ±5%
EEPROM
The microcontroller has 96 bytes of EEPROM memory available
for the system host.
A separate EEPROM IC, with write protect features, provides
another 128 bytes of memory. Minimum information to be
included in this separate EEPROM: model number, revision,
date code, serial number etc.
LEDs
Two LEDs are located on the front faceplate. The INPUT OK LED
provides visual indication of the INPUT signal function. When
the LED is ON GREEN the power supply input is within normal
design limits.
The second LED DC/FLT provides visual indication of three
different states of the power supply. When the LED is GREEN
then there are no faults and the DC output is present. When
the LED is AMBER then a fault condition exists but the power
supply still provides output power. When the LED is RED then a
fault condition exists and the power supply does not provide
output power.
GE
Data Sheet
CAR2512FP series rectifier
Input: 90V
AC
to 264V
AC
; Output: 12 V
DC
@ 2500W; 3.3V
DC
or 5 V
DC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 13
Alarm Table
Test Condition
LED Indicator Monitoring Signals
LED1
AC
Tri-Color LED2
DC / FLT FAULT DC OK INPUT OK TEMP OK
1 Normal Operation Green Green High High High High
2 Low or NO INPUT Off Red Low Low Low High
3 OVP Green Red Low Low High High
4 Over Current Green Red Low Low High High
5 Temp Alarm Warning Green Orange High
High High Low
6 Fault Over Temp Green Red Low Low High Low
7 Remote ON/OFF Green Red Low Low High High
Notes: Test condition #2 had 2 modules plug in. One module is running and the other one is with no AC.
Outline Drawing
airflow
AC
OK
DC
FLT
15.817 ±.020
15.375 ±.020
COVER
CHASSIS
0.330
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 14
Connector Pin Assignments
Input Mating Connector: IEC320, C19 type
Output Connector: Tyco P/N 6600122-7 or equivalent
Mating connector: Primary Source: FCI berg P/N 51915-176LF
Secondary Source: Tyco P/N 6450171-5
Pin Function Pin Function Pin Function Pin Function
A1 VSTDBY [3.3V] B1 Fault C1 IShare D1 VProg
A2 PS Present B2 I Monitor (IMON) C2 No connect D2 OVP Test Point
A3 Signal Return B3 Enable C3 Over Temp Warning D3 Remote ON/OFF
A4 Write Protect (WP) B4 VSTDBY [3.3V] Return C4 I2C Address (A0) D4 DC OK
A5 Remote Sense (+) B5 SDA (I2C bus) C5 I2C Address (A1) D5 AC OK
A6 Remote Sense (-) B6 SCL (I2C bus) C6 I2C Address (A2) D6 SMBAlert
P1 – P6 Output Return P7– P12 +12Vout
GE Data Sheet
CAR2512FP series rectifier
Input: 90VAC to 264VAC; Output: 12 VDC
@ 2500W; 3.3VDC
or 5 VDC
@ 1A
Contact Us
For more information, call us at
USA/Canada:
+1 888 546 3243, or +1 972 244 9288
Asia-Pacific:
+86.021.54279977*808
Europe, Middle-East and Africa:
+49.89.878067-280
India:
+91.80.28411633
www.ge.com/powerelectronics
April 23, 2013 ©2013 General Electric Company. All rights reserved. Page 15
Ordering Information
Please contact your GE Energy Sales Representative for pricing, availability and optional features.
PRODUCT DESCRIPTION PART NUMBER
2500W Front-End +12Vout Front-End, 3.3Vaux, with face plate and PMBus interface, RoHS 6 of 6 CAR2512FPBXXZ01A
2500W Front-End +12Vout Front-End, 5Vaux, with face plate and PMBus interface, RoHS 6 of 6 CAR2512FPBC5Z01A
PART NUMBER DEFINITION GUIDE EXAMPLE
CAR 25 12 FP x x x Z 01 A
RTM
RoHS
Blank – non compliant
Y – 5 of 6 compliant
Z – 6 of 6 compliant
Options
B – bezel
C – i2c option
R – reverse airflow
Vsb = 3
Output Power
25 = 250W
Output voltage
12 = 12Vdc
Type
FP – AC; V
o-
positive
DC - DC
A – Standard
model
Mouser Electronics
Authorized Distributor
Click to View Pricing, Inventory, Delivery & Lifecycle Information:
GE (General Electric):
CAR2512FPBC5Z01A CAR2512FPBXXZ01A