CC109149423 - GE CRITICAL POWER - Datasheet.Directory

GE Data Sheet



CP2725AC54TE Compact Power Line High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @



RoHS

Compliant



Applications



 48VDC distributed power architectures

 Routers/Switches

 VoIP/Soft Switches

 LAN/WAN/MAN applications

 File servers

 Indoor wireless

 Telecommunications equipment

 Enterprise Networks

 SAN/NAS/iSCSI applications



Description

Features

 Efficiency 96.2%

 Compact 1RU form factor with 30 W/in3 density

 Constant power from 52 – 58VDC

 2725W from nominal 200 – 277VAC

 1200W from nominal 100 – 120VAC

 Output voltage programmable from 42V – 58VDC



 PMBus compliant dual I2C and RS485 serial busses

 Isolated +5V Aux, signals and I2C communications

 Power factor correction (meets EN/IEC 61000-3-2 and



EN 60555-2

requirements)

 Output overvoltage and overload protection

 AC Input overvoltage and undervoltage protection

 Over-temperature warning and protection

 Redundant, parallel operation with active load sharing

 Remote ON/OFF

 Internally controlled Variable-speed fan

 Hot insertion/removal (hot plug)

 Four front panel LED indicators

 UL* Recognized to UL60950-1, CAN/ CSA† C22.2 No.

60950-1, and VDE‡ 0805-1 Licensed to

IEC60950-1

 CE mark meets 2006/95/EC directive§

 RoHS 6 compliant



 Conformally coated option



The CP2725AC54TE Rectifier provides significant efficiency improvements in the Compact Power Line platform of Rectifiers. High-

density front-to-back airflow is designed for minimal space utilization and is highly expandable for future growth. The wide-input

standard product is designed to be deployed internationally. It is configured with both RS485 and dual-redundant I2C

communications busses that allow it to be used in a broad range of applications. These signals and the 5V auxiliary supply are

isolated from the main output and frame ground. Feature set flexibility makes this rectifier an excellent choice for applications

requiring modular AC to - 48VDC intermediate voltages, such as in distributed power.



* 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.

§ This product is intended for integration into end-user equipment. All CE marking procedures 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

+ The PMBus name and logo are registered trademarks of the System Management Interface Forum

(SMIF)



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet

3 Internal protection circuits may override the PFW signal and may trigger an immediate shutdown.



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

300

Operating Ambient Temperature1

-10

°C

Storage Temperature Ts

-40

°C

I/O Isolation voltage to Frame (100% factory Hi-Pot tested)

1500



Electrical

Specifications



Unless otherwise indicated, specifications apply over all operating input voltage, Vo=54VDC, resistive load, and temperature

conditions.



INPUT

Parameter

Symbol

Min

Typ

Max

Unit

Startup Input Voltage

Low-line Operation

High-line Operation

 

185

Operating Voltage Range

Low-line Configuration

High-line Configuration

185

100 – 120

200 - 277



140

300

Input Voltage Swell (no damage)

305



Input Frequency F

Input Current; at

110

240



11.9

13.1



Inrush Transient (at 25°C, excluding X-Capacitor charging) I

Idle Power (at 220VAC) 54V OFF

54V ON @ Io=0



8.2



Input Leakage Current (265VAC, 60Hz) I

2.5

3.5

Power Factor (50 – 100% load) PF

0.96

0.995



Efficiency2 (30 – 80% of FL, 240VAC @ 25C) 

94.5

96.2



Holdup time (output allowed to decay down to

)

For loads below 1200W T 



Ride thru (tested at 115V @ 230V. (Complies to CISPR24) T

1/2

cycle

Power Fail Warning3 (main output allowed to decay to

)



Isolation (per EN60950) (consult factory for testing to this

requirement)

Input-Chassis/Signals

Input - Output

V 1500

3000





1 See the derating guidelines under the Environmental Specifications section

2 See efficiency curve in the Characteristics Curves section.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Electrical Specifications

(continued)



54VDC MAIN OUTPUT

Parameter

Symbol

Min

Typ

Max Unit

Output Power @ low line input 100 –

120V

@ high line input 200 –

277

@ nominal 277Vac and Tamb > 45C

1200

2725

2000



Default Set point



OUT

V

Overall regulation (load, temperature, aging) 0 - 45C LOAD > 2.5A

> 45C

-1

-2



Output Voltage Set Range - analog margining

- Set either by I2C or RS485



Output Current - @ 1200W (100 – 120Vac),

@ 2725W (200 – 240VAC), 54V/52V

@ 2000W ( > 277VAC @ Tamb > 45C), 54V/52V

Out



25/23

37/38.4

Current Share ( > 50% FL)

-5

Proportional Current Share between different rectifiers ( > 50% FL)



%FL

Output Ripple ( 20MHz bandwidth, load > 1A)

RMS (5Hz to 20MHz)

Peak-to-Peak (5Hz to 20MHz)

Psophometric Noise



OUT



100

300

rms

p-p

rms

External Bulk Load Capacitance C

OUT

5,000 F

Turn-On (monotonic turn-ON from 30 – 100% of Vnom above 5C)

Delay

Rise Time – PMBus mode

Rise Time - RS-485 mode6

Output Overshoot

OUT



100



Load Step Response ( IO,START > 2.5A )

I

V, VAC 

285

V, VAC ≥

285

Response Time

OUT



2.0

3.2



%FL

Overload - Power limit @ high line down to

Power limit @ low line down to

52V

High line current limit if Vout >

.5V

High line current limit if Vout <

41.5V

Low line current limit

Output shutdown (commences as voltage decays below this level)

System power up

OUT



OUT



OUT

2725

1200





Upon insertion the power supply will delay an overload shutdown

for 20 seconds allowing for the insertion and startup of multiple

modules within a system.

Overvoltage - 200ms delayed shutdown

Immediate shutdown

Latched shutdown

OUT

<

Three restart attempts are implemented within a 1 minute window

prior to a latched shutdown.

Over-temperature warning (prior to commencement of shutdown)

Shutdown (below the max device rating being protected)

Restart attempt Hysteresis (below shutdown level)



C

Isolation Output-Chassis (Standard, non-POE compliant)

Output-Chassis/Signals (POE compliant per IEEE802.3) V

500

2250

 V



4 500mVp-p max above 280VAC

input

or above 56Vdc output;

5 Complies with ANSI TI.523-2001 section 4.9.2 emissions max limit of 20mV flat unweighted wideband noise limits

6 Below -5°C, the rise time is approximately 5 minutes to protect the bulk capacitors.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



5VDC Auxiliary output

Parameter

Symbol

Min

Typ

Max Unit

Output Voltage Setpoint V

OUT

V

Overall Regulation

-10

Output Current 0.005

0.75

Ripple and Noise (20mHz bandwidth)

100

p-p

Over-voltage Clamp

Over-current Limit

110

175

%FL

Isolation from the main output STD / POE compliant 500 / 2250 Vd

Isolation from frame ground

Vd



General

Specifications



Parameter Min Typ Max Units

Note



Reliability 

450,000 Hours Full load, 25C ; MTBF per SR232 Reliability protection for

electronic equipment, issue 2, method I, case III,

Service Life 

Years Full load, excluding fans

Unpacked Weight 2.18/4.8 Kgs/Lbs

Packed Weight 2.45/5.4 Kgs/Lbs

Heat Dissipation 100 Watts or 341 BTUs @ 80% load, 153 Watts or 522 BTUs @ 100% load



Feature

Specifications



Unless otherwise indicated, specifications apply over all operating input voltage, resistive load, and temperature conditions. Signals are referenced

to Logic_GRD unless noted otherwise. Fault, PFW, OTW, SMBAlert#, and Power capacity need to be pulled HI through external pull-up resistors. See

Feature Descriptions for additional information.



Parameter Symbol Min Typ Max Unit

Enable (should be connected to Logic_GRD) 54V output OFF

54V output ON

OUT

1.4



0.8

Margining (through adjusting Vcontrol)

Voltage control range

Programmed output voltage range

Voltage adjustment resolution (8-bit A/D)

Output configured to

54V

Output configured to

44V

control

OUT

control



3.0



3.3



ON/OFF [short pin controls 54VDC output - ] referenced to VOUT( - )

54V output OFF

54V output ON

control

1.4





0.8

Module Present [Resistor connected to Logic_GRD internally]

Write protect enabled

Write protect disabled

500





0.8

Ω

Over Temperature Warning (OTW) Logic HI (temperature normal)

Sink current

Logic LO (temperature is too high)

0.7V



0.4

Fault Logic HI (No fault is present)

Sink current

Logic LO (Fault is present)



0.4

SMBAlert# (Alert#_0, Alert#_1) Logic HI (No Alert - normal)

Sink current

Logic LO (Alert is set)



0.4



7 Within ±5% when load is < 0.5A



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Feature Specifications (continued)

Parameter Symbol Min Typ Max Unit

Power Capacity Logic HI

Logic LO

0.7V



0.4

Reset Logic HI

Logic

0.7V







0.4

Protocol select Logic HI - Analog/PMBus™ mode

Logic – intermediate – RS485 mode

Logic LO – DSP reprogram mode

2.7

1.0









3.5

0.4



Digital Interface

Specifications



Parameter Conditions Symbol Min Typ Max Unit

PMBus Signal Interface Characteristics

Input Logic High Voltage (CLK, DATA) V 1.

3.6

Input Logic Low Voltage (CLK, DATA) V

0.8

Input high sourced current (CLK, DATA) I

Output Low sink Voltage (CLK, DATA, SMBALERT#) I

OUT

=3.5mA

Output Low sink current (CLK, DATA, SMBALERT#) I 3.



Output High open drain leakage current (CLK,DATA,

SMBALERT#) V

OUT

.6V I



PMBus Operating frequency range Slave Mode FPMB

400

Measurement System Characteristics

Clock stretching T

stretch

IOUT measurement range

Direct

rng

IOUT measurement accuracy 25°C I

out(acc)

-2.5

+2.5

% of FL

VOUT measurement range

Direct

out(rng)

VOUT measurement accuracy9 V

out(acc)

-1

Temp measurement range Di

rect

Temp

(rng)

150

C

Temp measurement accuracy10

Temp

(acc)

-5

VIN measurement range

Direct

in(rng)

320

VIN measurement accuracy V

in(acc)

-1.5

+1.5

PIN measurement range

Direct

in(rng)

3000

PIN measurement accuracy11

in(acc)

-3.5

+3.5

Fan Speed measurement range

Direct

30k

RPM

Fan Speed measurement accuracy

-10

Fan speed control range Di

rect

100

Device Addressing



Unit address [reference: VOUT ( - )]

Module 1 V

unitadr

2.477

3.3

Module 2 V

unitadr

1.925

2.2

Module 3 V

unitadr

1.243

1.5

Module 4 V

unitadr

0.654



Shelf address [reference: VOUT ( - )]

Shelf 1 V

shelfadr

3.3

3.45

Shelf 2 V

shelfadr

2.86

2.97

Shelf 3 V

shelfadr

2.4

2.56

Shelf 4 V

shelfadr

1.96

2.14

Shelf 5 V

shelfadr

1.50

1.70

Shelf 6 V

shelfadr

1.10

1.25

Shelf 7 V

shelfadr

0.60

0.80

Shelf 8 V

shelfadr

0.01

0.25



8 Load levels higher than 50A will be read as 50A.

9 Above 2.5A of load current

10 Temperature accuracy reduces non-linearly with decreasing temperature

11 Below 100W input power measurement accuracy reduces significantly



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Environmental

Specifications



Parameter

Min T

p Max Units

Notes

Ambient Temperature

-40



°C Air inlet from sea level to 5,000 feet.

Storage Temperature

-40

°C

Operating Altitude 1524/5000 m / ft

Non-operating Altitude 8200/30k m / ft

Power Derating with Temperature 

%/°C

55°C to

C

Power Derating with Altitude 

C/305 m

C/1000 ft

Above 1524/5000 m/ft; 3962/13000 m/ft

max

Acoustic noise 

dbA

Full load

Over Temperature Protection 125/110 °C Shutdown / restart [internally measured

points]

Humidity

Operating

Storage



Relative humidity, non-condensing



Shock and Vibration acceleration 

Grms NEBS GR-63-CORE, Level 3, 20 -2000Hz, min

30 minutes



Earthquake Rating





Zone

NEBS GR-63-CORE, all floors, Seismic Zone 4

Designed and tested to meet NEBS

specifications.



EMC

ameter Criteria

Standard

Level

Test



AC input

Conducted emissions EN55022, FCC Docket 20780 part 15, subpart J

EN61000-3-2

Meets Telcordia GR1089-CORE by a 3dB margin

0.15 – 30MHz

0 – 2 KHz

Radiated emissions EN55022

30 – 10000MHz



AC Input

Immunity

Line sags and

interruptions

EN61000-4-11

-30%, 10ms

-60%, 100ms

-100%, 5sec

Output will stay above 40VDC @ full load



Sag must be higher than 80Vrms.

25% line sag for 2 seconds

1 cycle interruption

Lightning surge EN61000-4-5, Level 4, 1.2/50µs – error free

4kV, common mode

2kV, differential mode

ANSI C62.41 - damage free

6kV, common & differential

Fast transients EN61000-4-4, Level 3

5/50ns, 2kV (common mode)



Enclosure

immunity

Conducted RF fields EN61000-4-6, Level 3

130dBµV, 0.15-80MHz, 80% AM

Radiated RF fields EN61000-4-3, Level 3

10V/m, 80-1000MHz, 80% AM

ENV 50140

ESD EN61000-4-2, Level 3

6kV contact, 8kV air



12 Designed to start and work at an ambient as low as -40°C, but may not meet operational limits until above -5°C

13 Output power is derated to 2kW for temperatures higher than 45C and input voltages higher than

285V

14 The maximum operational ambient is reduced in Europe in order to meet certain power cord maximum ratings of 70C. The maximum

operational ambient where 70C rated power cords are utilized is reduced to 60C until testing demonstrates that a higher level is acceptable.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



OUTPUT VOLTAGE

VO (V) (20mV/div) OUTPUT VOLTAGE EFFICIENCY,  (%)

OUTPUT VOLTAGE

VO (V) (20mV/div) OUTPUT POWER OUTPUT VOLTAGE



Characteristic

Curves

The following figures provide typical characteristics for the CP2725AC54TE rectifier and 25oC.



98 60

96

92 50

90 Vin=110V Vin=240V

86 40

84

80 0 5 10 15 20 25 30 35 40 45 50 55



30 40 45 50 55



OUTPUT CURRENT, IO (A) OUTPUT CURRENT

Figure 1. Rectifier Efficiency versus Output Current. Figure 2. 54VDC output: Power limit, Current limit and

shutdown profile at VIN = 185VAC.

60



30 15 20 25 30



OUTPUT CURRENT INPUT VOLTAGE

Figure 3. 54VDC output: Power limit, Current limit and

shutdown profile at VIN = 90VAC.

Figure 4. 54VDC output: Output power derating based on

input voltage.



TIME, t (10ms /div) TIME, t (10ms/div)



Figure 5. 54VDC output ripple and noise, full load,

VIN = 185VAC, 20MHz bandwidth



Figure 6. 5VDC output ripple and noise, all full load,

VIN = 185VAC, 20MHz Bandwidth



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



OUTPUT VOLTAGE

VO (V) (200mV/div)

OUTPUT

CIURRENT

IO (V)

(20A/div)

OUUTPUT

VOLTAGE

VO (V)

(1V/div)

INPUT VOLTAGE

VIN (V) (100V/div)

OUUTPUT

VOLTAGE

VO(V)

(10V/div)

PFW SIGNAL

VPFW (V) (5V/div)

OUUTPUT VOLTAGE

VO(V) (10V/div)

OUTPUT

CIURRENT

IO (V)

(20A/div)

OUUTPUT

VOLTAGE

VO(V)

(1V/div)

OUTPUT

VOLTAGE

VO (V)

(10V/div)



Characteristic Curves

(continued)

The following figures provide typical characteristics for the CP2725AC54TE rectifier and 25oC.

TIME, t (20ms/div) OUTPUT CURRENT, IO (A)

Figure 7. Transient response 54VDC load step 2.5 – 27.2A,

VIN = 185VAC.

Figure 8. Transient response 54VDC load step 27.2 – 2.5A,

VIN = 185VAC.

TIME, t (50ms/div) TIME, t (2s/div)

Figure 9. 54VDC soft start, no-load & full load, VIN=185VAC -

I2C mode.

Figure 10. 54VDC soft start, full load, VIN = 185VAC -

RS485 mode.

TIME, t (10ms/div) TIME, t (10ms/div)



Figure 11. Ride through missing 1 cycle, full load,

VIN = 230VAC.



Figure 12. PFW alarmed 19.6ms prior to Vo < 40V,

output load: 38A, VIN = 185VAC.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @



Shelf_address

Maximum voltage 3.45 2.97 2.56 2.14

Nominal voltage 3.30 2.86 2.4 1.96

Minimum voltage 3.00 2.60 2.18 1.73

Address bit- A2 0 1 0 1

Out pu t Set poi nt (Vd c)

Ins ide

mod ule

10k

Rpr og ram



Control and

Status

The Rectifier provides three means for monitor/control: analog,

PMBus™, or the GE Galaxy-based RS485 protocol.

Details of analog control and the PMBus™ based protocol are

provided in this data sheet. GE will provide separate

application notes on the Galaxy RS485 based protocol for

users to interface to the rectifier. Contact your local GE

representative for details.



Signal Reference

Unless otherwise noted, all signals are referenced to

-58



-54



-46

-44



0 0.1 3.3



Vcontrol



3.3Vdc

Logic_GRD. See the Signal Definitions Table at the end of this Vcontrol (Vdc) 3.0

document for further description of all the signals.

Logic_GRD is isolated from the main output of the power

supply for PMBus communications. Communications and the

5V standby output are not connected to main power return

(Vout(-)) and can be tied to the system digital ground point

selected by the user. (Note that RS485 communications is

referenced to Vout(-), main power return of the power supply).

Logic_GRD is capacitively coupled to Frame_GRD inside the

power supply. The maximum voltage differential between

Logic_GRD and Frame_GRD should be less than 100VDC.



Control

Signals

Enable: Controls the main 54VDC output when either analog

control or PMBus protocols are selected, as configured by the

Protocol pin. This pin must be pulled low to turn ON

the rectifier.

The rectifier will turn OFF if either the Enable or the ON/OFF pin

is released. This signal is referenced to Logic_GRD. In RS485

mode this pin is ignored.

ON/OFF: This is a shorter pin utilized for hot-plug

applications

ensure that the rectifier turns OFF before the power pins are

disengaged. It also ensures that the rectifier turns ON only

after the power pins have been engaged. Must be connected

to V_OUT ( - ) for the rectifier to be ON.

Margining: The 54VDC output can be adjusted between 44 –

58VDC by a control voltage on the Margin pin. This control

voltage can be generated either from an external voltage

source, or by forming a voltage divider between 3.3V and

Logic_GRD, as shown in Fig. 13. The power supply includes the

high side pull-up 10kΩ resistor to 3.3VDC. Connecting a resistor

between the margin pin and Logic_GRD will complete the

divider.

An open circuit, or a voltage level > 3.0VDC, on this pin sets the

main output to the factory default setting of 54VDC.

Hardware margining is only effective until software

commanded output voltage changes are not executed.

Software commanded output voltage settings permanently

override the hardware margin setting until power to the

internal controller is interrupted, for example if input power or

bias power is recycled.

The controller always restarts into its default configuration,

programmed to set the output as instructed by the margin pin.

Subsequent software commanded settings permanently

override the margin pin. Adding a resistor between margin and

Vout(-) is an ideal way of changing the factory set point of the

rectifier to whatever voltage level is desired by the user.

Figure 13. Diagram showing how output can be margined

using Vcontrol adjustment.



Module Present Signal: This signal has dual functionality. It

can be used to alert the system when a rectifier is inserted. A

500Ω resistor is present in series between this signal and

Logic_GRD. An external pull-up should not raise the voltage on

the pin above 0.25VDC. When the voltage on this pin exceeds

1VDC, the write_protect feature of the EEPROM is enabled.

8V_INT: Single wire connection between modules, Provides

bias to the DSP of an unpowered module.

Reset: This is a PCA9541 multiplexer function utilized during

PMBus communications. If momentarily grounded (Logic_GRD),

the multiplexer would reset itself.

Protocol: Establishes the communications mode of the

rectifier, between analog/PMBus and RS485 modes. For RS485,

connect a 10kΩ pull-down resistor from this pin to V_OUT( - ).

For analog/PMBus leave the pin open. Do not tie this signal pin

to V_OUT( - ) because that connection configures the internal

DSP into a reprogrammed state.

Unit Address: Each module has an internal 10kΩ resistor

pulled up between unit_address and 3.3VDC. A resistor

between unit_address and Vout(-) sets the appropriate unit

address.



I2C address

Rectifier Resistor Value Nominal voltage

30K

477

14K

925

243

654



Shelf Address: By applying the required voltage between the

shelf address pin and Vout(-), up to 8 different shelves and so

up to 32 different modules can be addressed using either the

PMBus or GE Galaxy based RS485 protocol.

PMBus addressing is limited to a maximum of 8 modules and

so the software decodes the shelf address setting into either

shelf 0 or shelf 1 in PMBus applications. If more than two

shelves are paralleled, the user must separate the I2C lines so

that address conflicts do not occur.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Shelf_address

Maximum voltage 1.70 1.25 0.80 0.25

Nominal voltage 1.50 1.10 0.60 0.01

Minimum voltage 1.29 0.84 0.30 0

Address bit- A2 0 1 0 1



Status

Signals



Power Capacity: A HI on this pin indicates that the rectifier

delivers high line rated output power; a LO indicates that the

rectifier is connected to low line configured for 1200W

operation.



Power Fail Warning: This signal is HI when the main output is

being delivered and goes LO for the duration listed in this data

sheet prior to the output decaying below the listed voltage

level.

Fault: This signal goes LO for any failure that requires rectifier

replacement. These faults may be due to:

 Fan failure

 Over-temperature warning

 Over-temperature shutdown

 Over-voltage shutdown

 Internal Rectifier Fault



Digital Feature

Descriptions

PMBus™ compliance: The power supply is fully compliant to

the Power Management Bus (PMBus™) rev1.2 requirements

with the following exceptions:

The power supply continuously updates its STATUS and ALARM

registers to the latest state in order to capture the ‘present’

state of the power supply. There are a number of indicators,

such as those indicating a communications fault (PEC error,

data error) that do not get cleared until specifically instructed

by the host controller sending a clear_faults command. A ‘bit’

indicator notifies the user if the STATUS and ALARM registers

changed since the last ‘read’ by the host controller.

For example, if a voltage surge causes a momentary shutdown

for over voltage the power supply will automatically restart if

the ‘auto_restart’ feature is invoked. During the momentary

shutdown the power supply issues an Alert# indicating to the

system controller that a status change has occurred. If the

system controller reads back the STATUS and ALARM registers

while the power supply is shut down it will get the correct fault

condition. However, inquiry of the state of the power supply

after the restart event would indicate that the power supply is

functioning correctly. The STATUS and ALARM indicators

did not

freeze at the original shutdown state and so the reason for the

original Alert# is erased. The restart ‘bit’ would be set to indicate

that an event has occurred.

The power supply also clears the STATUS and ALARM registers

after a successful read back of the information in these

registers, with the exception of communications error alarms.

This automated process improves communications efficiency

since the host controller does not have to issue another

clear_faults command to clear these registers.

Dual, redundant buses: Two independent I2C lines provide true

communications bus redundancy and allow two independent

controllers to sequentially control the power supply. For

example, a short or an open connection in one of the I2C lines

does not affect communications capability on the other I2C line.

Failure of a ‘master’ controller does not affect the power

supplies and the second ‘master’ can take over control at any

time.

Using the PCA9541 multiplexer: Transition between the two

I2C lines is provided by the industry standard PCA9541 I2C

master selector multiplexer. Option 01 of the device code is

supplied which, upon start-up, connects channel 0 to the

power supply. In this fashion applications using only a single

I2C line can immediately start talking across the bus without

first requiring to reconfigure the multiplexer.



Figure 14. Diagram showing conceptual representation

of the dual I2C bus system.



Control can be taken over at any time by a specific ‘master’

even during data transmission to the other ‘master’. The

‘master’ needs to be able to handle incomplete transmissions

in the multi-master environment in case switching should

commence in the middle of data transmission.

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 power supply may initiate clock

stretching if it is busy. The ‘slave’ may keep the clock LO until it

is ready to receive instructions. The maximum clock stretch

interval is 25ms.



The host needs to refrain from issuing the next clock signal

until the clock is released, or it needs to delay the next clock

pulse beyond the clock stretch interval of the power supply.



Note that clock stretching occurs after the 9th (ACK) bit, the

exception being the START command.



Clock

Stretch

Figure 14. Example waveforms showing clock stretching.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Communications speed: Both 100kHz and 400kHz clock rates

are supported. The power supplies default to the 100kHz clock

rate.

Packet Error Checking: The power supply will not respond to

commands without the trailing PEC. 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 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.

SMBusAlert#: The power supply can issue SMBAlert# driven

from either its internal micro controller (µC) or from the

PCA9541 I2C bus master selector. That is, the SMBAlert# signal

of the internal µC funnels through the PCA9541

master

selector

that buffers the SMBAlert# signal and splits the signal

to the two SMBAlert# signal pins exiting the power supply. In

addition, the PCA9541 signals its own SMBAlert# request to

either of the two SMBAlert# signals when required.

Non-supported commands: Non supported commands are

flagged by setting the appropriate STATUS bit and issuing an

SMBAlert# to the ‘host’ controller.

Data out-of-range: The power supply validates data settings

and sets the data out-of-range bit and SMBAlert# if the data is

not within acceptable range.

SMBAlert# triggered by the µC: The µC driven SMBAlert#

signal informs the ‘master/host’ controller that either a

STATE

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 receives a ‘clear’ instruction as outlined below. If

the alarm state is still present after the ‘clear_faults’ command

has been received, then the signal will revert back into its LO

level again and will latch until a subsequent ‘clear’ 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:

 Completion of a ‘read_status’ instruction

 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

SMBAlert# triggered by the PCA9541: If clearing the Alert#

signal via the clear_faults or read back fails, then reading back

the Alert# status of the PCA9541 will be necessary followed by

clearing of the PCA9541 Alert#.

The PCA9541 can issue an Alert# even when single bus

operation is selected where the bus master selector has not

been used or addressed. This may occur because the default

state of the PCA9541/01 integrated circuit issues Alert# to both

i2C lines for all possible transitioning states of the device. For

example, a RESET caused by a glitch would cause the Alert# to

be active.

If the PCA9541 is not going to be used in a specific application

(such as when only a single I2C line is utilized), it is imperative

that interrupts from the PCA9541 are de-activated by the host

controller. To de-activate the interrupt registers the PCA9541

the ‘master’ needs to address the PCA9541 in the ‘write’ mode,

the interrupt enable (IE) register needs to be accessed and the

interrupt masks have to be set to HI ‘1’. (Note: do not mask bit

0 which transmits Alert# from the power supply). This

command setting the interrupt enable register of the PCA9541

is shown below;



Start Unit Address ACK

1 7 6 5 4 3 2 1 0

S 1 1 1 0 A2 A1 A0 0



Command Code ACK IE Register Stop

0x0E



There are two independent interrupt enable (IE) registers, one

for each controller channel (I2C-0 and I2C-1). The interrupt

independently. That is, channel I2C-0 cannot configure the IE

This command has to be initiated to the PC9541 only once

after application of power to the device. However, every time a

restart occurs the PCA9541 has to be reconfigured since its

default state is to issue Alert# for changes to its internal status.

If the application did not configure the interrupt enable register

the Alert# line can be cleared (de-activated), if it has been

activated by the PCA9541, by reading back the data from the

interrupt status registers (Istat).

Refer to the PCA9541 data sheet for further information on

how to communicate to the PCA9541 multiplexer.

Please note that the PCA9541 does not support Packet Error

Checking (PEC).

Re-initialization: The I2C code is programmed to re-initialize if

no activity is detected on the bus for 5 seconds. Re-

initialization is designed to guarantee that the I2C µController

does not hang up the bus. Although this rate is longer than the

timing requirements specified in the SMBus specification, it



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Command Hex Data

Function

Code Field

Operation

Output ON/OFF

Clear_Faults

Clear Status

Vout_command

Set Vout

Vout_OV_fault_limit

Set OV fault limit

Read_status

Read Status, Vout, Iout, T

LEDs test ON

Test LEDs

LEDs test OFF

Service_LED_ON

Service LED

Service_LED_OFF

Enable_write

Enable EEPROM write

Disable_write

Disable EEPROM write

Inhibit_restart D

Latch upon failure

Auto_restart D

Hiccup

Isolation_test D

Perform isolation test

Read_input_string DC

Read Vin and Pin

Read_firmware_rev DD

Firmware revisions

Read_run_timer DE

Accumulated ON state

Fan_speed_set DF

Fan speed control

Fan_normal_speed

Stop fan control

Read_fan_speed

Fan control & speed

Stretch_LO_25ms

Production test feature

FUNCTION DATA BYTE

Unit ON

Unit OFF



had to be extended in order to ensure that a re-initialization

would not occur under normal transmission rates. During the

few µseconds required to accomplish re-initialization the I2C

µController may not recognize a command sent to it. (i.e. a

start condition).

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.

Note: The PCA9541 i2c master selector does not respond to the

GLOBAL BROADCAST command.

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

one second. This time interval is sufficient for the internal

processors to update their data base so that successive reads

provide fresh data.

Device ID: Address bits A2, A1, A0 set the specific address of

the power supply. The least significant bit x (LSB) of the address

byte configures write [0] or read [1] events. In a write

command the system instructs the power supply. In a read

command information is being accessed from the power

supply.



Low data byte A High data byte A PEC A



Master to Slave Slave to Master

SMBUS annotations; S – Start , Wr – Write, Sr – re-Start, Rd – Read,

A – Acknowledge, NA – not-acknowledged, P – Stop

Direct mode data format: The Direct Mode data format is

supported, where y = [ mX + b ] x 10R . In the equation, y is the

data value from the controller and x is the ‘real’ value either

being set or returned. except for VIN and Fan

speed

, x is the

data value from the controller and y is the ‘real’ value.



For example, to set the output voltage to 50.45VDC, Multiply the

desired set point by the m constant, 50.45 x 400 = 20,180.

Convert this binary number to its hex equivalent: 20,180b =

0x4ED4. The result is sent LSB=0xD4 first, then MSB=0x4E.

The constants are



FUNCTION Operation m b R

Output voltage

Output voltage shutdown

Write / read 400

Output Current

read

Temperature

read

Input Voltage

read

Input Power

read

Fan Speed setting ( % )

read

Fan speed in RPM

read

100



PMBusTM Command set:



Address

Bit

7 6 5 4 3 2 1 0

PCA9541 1 1 1 0 A2 A1 A0 R/W

Micro controller 1 0 0 0 A2 A1 A0 R/W

External EEPROM 1

1 0 A2 A1 A0 R/W

Global Broadcast 0 0 0 0 0 0 0 0

MSB LSB



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.



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

mandatory and includes the address and data fields.



Command

Descriptions

Operation (01h) : By default the Power supply is turned ON at

power up as long as ENABLE is active LO. The Operation

command is used to turn the Power Supply ON or OFF via the

PMBus. The data byte below follows the OPERATION command.



S Slave address Wr A Command Code



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Bit

Title

Description

spare

Isolation test OK Isolation test completed successfully.

Internal fault The power supply is faulty

Shutdown

Service LED ON ON = 1

External fault the power supply is functioning OK

LEDs flashing LEDs tested test ON = 1

Output ON ON = 1



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 (03h): This command clears information bits in

the STATUS registers, these include:



 Isolation OK

 Isolation test failed

 Restarted OK

 Invalid command

 Invalid data

 PEC error

Vout_Command (21h) : 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 overrides the set

point voltage configured during power_up. The program no

longer looks at the ‘margin pin’ and will not respond to any

hardware voltage setting. The default state cannot be

accessed any longer unless power is removed from the DSP.

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.

Voltage margin range: 42VDC – 58

A voltage programming example: The task: set the output

voltage to 50.45VDC

The constants for voltage programming are: m = 400, b and R

= 0. Multiply the desired set point by the m constant, 50.45 x

400 = 20,180. Convert this binary number to its hex equivalent:

20,180b = 4ED4h. Transmit the data LSB first, followed by MSB,

0 x D44Eh.

Vout_OV_fault_limit (40h) : This command sets the Output

Overvoltage Shutdown level.

Manufacturer-Specific PMBusTM

Commands

Many of the

manufacturer-specific

commands read back more

than two bytes. If more than two bytes of data are returned,

the standard SMBusTM Block read is utilized. In this process, the

Master issues a Write command followed by the data transfer

from the power supply. The first byte of the Block Read data

field sends back in hex format the number of data bytes,

exclusive of the PEC number, that follows. Analog data

always

transmitted LSB followed by MSB. A No-ack following

the PEC byte signifies that the transmission is complete and is

being terminated by the ‘host’.

Read_status (D0h) : This ‘manufacturer specific’ command is

the basic read back returning STATUS and ALARM

data,

output voltage, output current, and internal temperature

data in a single read.



Slave address Wr

Command Code



Sr Slave address Rd

Byte count = 9



Status-2

Status-1

Alarm-2



Alarm-1

Voltage LSB

Voltage MSB



Current

Temperature

PEC NA



Status and alarm registers



The content and partitioning of these registers is significantly

different than the standard register set in the PMBus™

specification. More information is provided by these registers

and they are accessed rapidly, at once, using the ‘multi

parameter’ read back scheme of this document. There are a

total of four registers. All errors, 0 – normal, 1 – alarm.



Status-2



Bit

Title

Description

PEC Error Mismatch between computed and

transmitted PEC. The instruction has

not been executed. Clear_Flags

resets this register.

Will Restart Restart after a shutdown = 1

Invalid Instruction The instruction is not supported. An

ALERT# will be issued. Clear_Flags

resets this register.

Power Capacity High line power capacity = 1

Isolation test

failed

Information only to system controller

Restarted ok Informs HOST that a successful

RESTART occurred clearing the status

and alarm registers

Data out of range Flag appears until the data value is

within range. A clear_flags

command does not reset this register

until the data is within normal range.

Enable pin HI State of the ENABLE pin, HI = 1 = OFF



Isolation test failed: The ‘system controller’ has to determine

that sufficient capacity exists in the system to take a power

supply ‘off line’ in order to test its isolation capability. Since the

power supply cannot determine whether sufficient redundancy

is available, the results of this test are provided, but the

‘internal fault’ flag is not set.



Status-1



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Alarm-2



Bit Title Description

Fan Fault

No primary No primary detected

Primary OT Primary section OT

DC/DC OT DC/DC section OT

Output voltage

lower than bus

Internal regulation failure

Thermal sensor

failed

Internal failure of a temperature

sensing circuit

5V out_of_limits Either OVP or OCP occurred

Power delivery a power delivery fault occurred



Power Delivery: The power supply compares its internal

sourced current to the current requested by the current share

pin. If the difference is > 10A, a fault is issued.



Alarm-1



Bit Title Description

Unit in power limit An overload condition that results in

constant power

Primary fault Indicates either primary failure or

INPUT not present. Used in

conjunction with bit-0 and Status_1

bits 2 and 5 to assess the fault.

Over temp.

shutdown

One of the over_temperature

sensors tripped the supply

Over temp warning Temperature is too high, close to

shutdown

In over current Shutdown is triggered by low

output voltage <

39V

Over voltage

shutdown 

Vout out_of_limits Indication the output is not within

design limits. This condition may or

may not cause an output shutdown.

Vin out_of_limits The input voltage is outside design

limits



LEDS test ON (D2h) : Will turn-ON simultaneously the four

front panel LEDs of the Power supply sequentially 7 seconds

ON and 2 seconds OFF until instructed to turn OFF. The intent

of this function is to provide visual identification of the power

supply being talked to and also to visually verify that the LEDs

operate and driven properly by the micro controller.

LEDS test OFF (D3h) : Will turn-OFF simultaneously the four

front panel LEDs of the Power supply.

Service LED ON (D4h) : Requests the power supply to flash-ON

the Service (ok-to-remove) LED. The flash sequence is

approximately 0.5 seconds ON and 0.5 seconds OFF.

Service LED OFF (D5h) : Requests the power supply to turn OFF

the Service (ok-to-remove) LED.

Enable write (D6h) : This command enables write permissions

into the upper ¼ of memory locations for the external

EEPROM. A write into these locations is normally disabled until

commanded through I2C to permit writing into the protected

area. A delay of about 10ms is required from the time the

instruction is requested to the time that the power supply

actually completes the instruction.

See the FRU-ID section for further information of content

written into the EEPROM at the factory.

Disable write (D7h) : This command disables write permissions

into the upper ¼ of memory locations for the external

EEPROM.

Unit in Power Limit or in Current Limit: When output voltage

is > 36VDC the Output LED will continue blinking.

When output voltage is < 36VDC, if the unit is in the RESTART

mode, it goes into a hiccup. When the unit is ON the output

LED is ON, when the unit is OFF the output LED is OFF.

When the unit is in latched shutdown the output LED is OFF.

Inhibit_restart (D8h) : The Inhibit-restart command directs

the power supply to remain latched off for over_voltage,

over_temperature and over_current. The command needs to

be sent to the power supply only once. The power supply will

remember the INHIBIT instruction as long as internal bias is

active.

Restart after a lachoff: To restart after a latch_off either of

four restart mechanisms are available. The hardware pin

Enable 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, set the

restarted successful bit of the Status_2 register.

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 ENABLE 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.

Auto_restart (D9h) : Auto-restart is the default configuration

for overvoltage, overcurrent and overtemperature shutdowns.

However, overvoltage has a unique limitation. 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 within the 1 minute less than 3 shutdowns

occurred then the count for latch OFF resets and the 1 minute

window starts all over again.

This command resets the power supply into the default auto-

restart configuration.

Isolation test (DAh): This command verifies functioning of

output OR’ing. At least two paralleled power supplies are

required. The host should verify that N+1 redundancy is

established. If N+1 redundancy is not established the test can

fail. Only one power supply should be tested at a time.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Slave address Wr

Command Code 0xDC

Sr Slave Address Rd

S Slave address Wr ACommand 0xE1

Sr Slave address Rd A Byte count = 5 A

Adjustment %

Fan-1

Fan-2

Fan-3

PEC NA P

Slave address Wr A Command Code 0xDE A

Sr Slave Address Rd A Byte count = 4 A

Time - LSB A Time A Time - MSB A

PEC No-ack P



Verifying test completion should be delayed for approximately

30 seconds to allow the power supply sufficient time to

properly execute the test.

Failure of the isolation test is not considered a power supply

FAULT because the N+1 redundancy requirement cannot be

verified. The user must determine whether a true isolation fault

indeed exists.

Read input string (DCh) : Reads back the input voltage and

input power consumed by the power supply. In order to

improve the resolution of the input voltage reading the data is

shifted by 75V.



Fan_speed_set (DFh) : This command instructs the power

supply to increase the speed of the fan. The transmitted data

byte represents the hex equivalent of the duty cycle in

percentage, i.e. 100% = 0 x 64h. The command can only

increase fan speed, it cannot instruct the power supply to

reduce the fan speed below what the power supply requires

for internal control.

Fan_normal_speed (E0h): This command returns fan control

to the power supply. It does not require a trailing data byte.

Read_Fan_speed (E1h) : Returns the commanded fan speed in

percent and the measured fan speed in RPM from

the individual

fans. Up to 3 fans are supported. If a fan does not exist (units

may contain from 1 to 3 fans), or if the command is

not supported the unit return 0x00.



Byte Count = 4

Voltage



Power - LSB A Power - MSB A PEC No-ack P



Read_firmware_rev [0 x DD]: Reads back the firmware

revision of all three µC in the power supply.



Slave address Wr

Command Code 0xDD A



Sr Slave Address Rd

Byte Count = 4



Primary micro revision

DSP revision



I2c Micro revision

PEC No-ack



For example; the read returns one byte for each device (i.e. 0 x

002114h ). The sequence is primary micro, DSP, and I2C micro.

0x00 in the first byte indicates that revision information for the

primary micro is not supported. The number 21 for the DSP

indicates revision 2.1, and the number 14 for the i2c micro

indicates revision 1.4.

Read_run_timer [0 x DE]: This command reads back the

operational ON state in hours. The operational ON state is

accumulated from the time the power supply is initially

programmed at the factory. The operational ON state includes

standby and delivery of main output power. Recorded

capacity is approximately 10 years.

Stretch_LO_25ms (E2h) : Command used for production test

of the clock stretch feature.

None supported commands or invalid 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.



Fault

Management

The power supply records faults in the STATUS and ALARM

registers above and notifies the MASTER controller as

described in the Alarm Notification section of the non-

conforming event.

The STATUS and ALARM registers are continuously

updated with

the latest event registered by the rectifier monitoring circuits. A

host responding to an SMBusALERT# signal may receive a

different state of the rectifier if the state has changed from the

time the SMBusALERT# has been triggered by the rectifier.

The power supply differentiates between internal faults that

are within the power supply and external faults that the

power supply protects itself from, such as overload or input

voltage out of limits. The FAULT LED, FAULT PIN or i2c alarm is

not asserted for EXTERNAL FAULTS. Every attempt is made to

annunciate External Faults. Some of these annunciations can

be observed by looking at the input LEDs. These fault

categorizations are predictive in nature and therefore there is

a likelihood that a categorization may not have been made

correctly.

Input voltage out of range: The Input LED will continue

blinking as long as sufficient power is available to power the



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



LED. If the input voltage is completely gone the Input LED is

OFF.



tate Change

Definition

A state_change is an indication that an event has occurred

that the MASTER should be aware of. The following events

shall trigger a state_change;

 Initial power-up of the system when AC gets turned ON .

This is the indication from the rectifier that it has been

turned ON. Note that the master needs to read the status

of each power supply to reset the system_interrupt. If the

power supply is back-biased through the 8V_INT or the

5VSTB it will not issue an SMBALERT# when AC power is

turned back ON.



 Whenever the power supply gets hot-plugged into a

working system. This is the indicator to the system

(MASTER) that a new power supply is on line.



 Any changes in the bit patterns of the STATUS and ALARM

registers are a STATUS change which triggers the

SMBALERT# flag. Note that a host-issued command such

as CLEAR_FAULTS will not trigger an SMB



Hot plug

procedures

Careful system control is recommended when hot plugging a

power supply into a live system. It takes about 15 seconds for

a power supply to configure its address on the bus based on

the analog voltage levels present on the backplane. If

communications are not stopped during this interval, multiple

power supplies may respond to specific instructions because

the address of the hot plugged power supply always defaults

to xxxx000 (depending on which device is being addressed

within the power supply) until the power supply configures its

address.

The recommended procedure for hot plug is the following: The

system controller should be told which power supply is to be

removed. The controller turns the service LED ON, thus

informing the installer that the identified power supply can be

removed from the system. The system controller should then

poll the module_present signal to verify when the power

supply is re-inserted. It should time out for 15 seconds after

this signal is verified. At the end of the time out all

communications can resume.



Predictive

Failures

Alarm warnings that do not cause a shutdown are

indicators

potential future failures of the power supply. For example, if

a thermal sensor failed, a warning is issued but an immediate

shutdown of the power supply is not warranted.



Another example of potential predictive failure mechanisms

can be derived from information such as fan speed when

multiple fans are used in the same power supply. If the speed

of the fans varies by more than 20% from each other, this is an

indication of an impending fan wear out.



The goal is to identify problems early before a protective

shutdown would occur that would take the power supply out

of service.

External

EEPROM

A 64k-bit EEPROM is provided across the I2C bus. This EEPROM

is used for both storing FRU_ID information and for providing a

scratchpad memory function for customer use.

Functionally the EEPROM is equivalent to the ST M34D64 part

that has its memory partitioned into a write protected upper ¼

of memory space and the lower ¾ section that cannot be

protected. FRU_ID is written into the write protected portion of

memory.

Write protect feature: Writing into the upper 1/4 of memory

can be accomplished either by hardware or software.

The power supply pulls down the write_protect (Wp) pin to

ground via a 500Ω resistor between the ‘module_present’

signal pin and Logic_GRD (see the Module Present Signal

section of Input Signals). Writing into the upper ¼ of memory

can be accomplished by pulling HI the module_present pin.

An alternative, and the recommended approach, is to issue the

Enable_write command via software.

Page implementation: The external EEPROM is partitioned into

32 byte pages. For a write operation only the starting

address

required. The device automatically increments the memory

address for each byte of additional data it receives.

However, if

the 32 byte limit is exceeded the device executes a wrap-

around that will start rewriting from the first address specified.

Thus byte 33 will replace the first byte written, byte 34 the

second byte and so on. One needs to be careful therefore not

to exceed the 32 byte page limitation of the device.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @



Table 1:

FRU_ID



The upper quarter of memory starting from address 6144 shall be reserved for factory ID and factory data.

Memory Memory

Location Location

Decimal (HEX)

Length

(bytes)

Format Static Description

Value

Type

tes/Example

6144d 0x1800

ASCII Fixed GE-energy - Product ID CP2725AC54TE

6156d 0x180C

ASCII Fixed GE-energy – Part Number 123456789x or C123456789

6166d 0x1816

ASCII Variable GE-energy - Hardware revision x:xxxx controlled by PDI series #

6172d 0x181C

ASCII Variable spare

6178d 0x1822

ASCII Variable GE-energy - Serial_No 01KZ51018193xx

01 …. Year of manufacture - 2001

KZ … factory, in this case Matamoros

51 .. week of

manufacture

018193xx serial # mfg choice

6192d 0x1830

ASCII Variable GE- Manufacturing location “Matamoros, Tamps, Mexico”

6232d 0x1858

ASCII Fixed spare

6240d 0x1860

HEX Fixed spare

6242d 0x1862 158 ASCII Fixed Customer Information These fields are reserved for use by the

customer.

6400d 0x1900

HEX Fixed M, B, & R for voltage read M & B are 2 bytes each sent as MSB and then

LSB. R is one byte. These are stored as two’s

complement.



See the section on Direct Mode Constants

Stored in the EEPROM for the constants stored

in these fields

6405d 0x1905

HEX Fixed M, B, & R for current read

6410d 0x190A

HEX Fixed M, B, & R temp read

6415d 0x190F

HEX Fixed spare

6420d 0x1914

HEX Fixed M, B, & R for voltage set

6425d 0x1919

HEX Fixed M, B, & R for input voltage read

6430d 0x191E

HEX Variable Validation CHKSUM

6431d 9x191F

HEX Fixed M, B, & R for input power read

6436d 0x1924

HEX Fixed M, B, & R for fan percent adjust

6441d 0x1929

HEX Fixed M, B, & R for fan RPM read

6446d 0 x 192E

HEX Fixed M, B, & R for converter input

voltage read

Notes:

Memory locations 0x00 to 0x17FF and 0x1A00 to 0x2000 are blank (0xFF). Locations 0x1800 to 0x19FF contain FRUID, locations not specified are

filled with 0’s. Checksum is the complement of the sum of locations 0x1800 to 0x19FF (chksum = 0xFF – sum(0x1800-0x19FF)), excluding serial

number field (checksum will always be the same since all fields are fixed except serial number).



Table 2: Alarm and LED state

summary



Power Supply LED State Monitoring Signals



ndi

tion

Green

DC OK

Green

Service

Amber

Faul

Red

Fault OTW



PFW

Module

Present

HI HI HI

Thermal Alarm (5C before shutdown)

O HI

Thermal Shutdown

Defective Fan

Blown AC Fuse in Unit

AC Present but not within limits Blinks

HI HI

—

AC not present1

HI HI

Boost Stage Failure

Over Voltage Latched Shutdown

Over Current

Blinks

HI HI

Non-catastrophic Internal Failure2

HI HI

Missing Module   HI

Standby (remote)

HI HI

Service Request (PMBus mode)

Blinks

HI HI HI

Communications Fault (RS485 mode)

Blinks HI HI HI



1 This signal is correct if the rectifier is back biased from other rectifiers in the shelf .

2 Any detectable fault condition that does not cause a shutting down. For example, ORing FET failure, boost section out of regulation, etc.

3 Signal transition from HI to LO is output load dependent

4 The PFW signal changes states when the boost voltage decays and not when the AC is out of regulation.



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Table 3: Signal

Definitions



All hardware alarm signals (Fault, PFW, OTW, Power Capacity) are open drain FETs. These signals need to be pulled HI to either 3.3V or 5V.

Maximum sink current 5mA. An active LO signal (< 0.4VDC) state. All signals are referenced to Logic_GRD unless otherwise stated.

Function

Label

Description

Output Enable Enable Input If shorted to Logic_GRD main output is ON in Analog or PMBus mode.

Power Fail Warning PFW Output An open drain FET; Changes to LO  5msec before the output decays below

I2C Interrupt Alert#_0/Alert#_1 Output This signal is pulled to 3.3V via a 10kΩ resistor. Active LO.

Rectifier Fault Fault Output An open drain FET; normally HI, changes to LO.

Module Present MOD_PRES Output Short pin, see Status and Control description for further information on this signal.

ON/OFF ON/OFF Input Short pin, controls main output during hot-insertion and extraction. Ref: Vout ( - )

Protocol select Protocol Input Selects operational mode. Ref: Vout ( - ). No-connect PMBus, 10kΩ - RS485

Margining Margin Input Changes the default set point of the main output.

Over-Temperature Warning OTW Output Open drain FET; normally HI, changes to LO 5°C prior to thermal shutdown.

Power Capacity POWER_CAP Output Open drain FET; HI indicates 2725W operation and LO indicates 1200W operation.

Rectifier address Unit_addr Input Voltage level addressing of Rectifiers within a single shelf. Ref: Vout ( - ).

Shelf Address Shelf_addr Input Voltage level addressing of Rectifiers within multiple shelves. Ref: Vout ( - ).

Back bias 8V_INT Bi-direct Used to back bias the DSP from operating Rectifiers. Ref: Vout ( - ).

Mux Reset Reset Input Resets the internal PCA9541 multiplexer

Standby power 5VA Output 5V at 0.75A provided for external use

Current Share Ishare Bi-direct A single wire active-current-share interconnect between modules Ref: Vout ( - ).

I2C Line 0 SCL_0 Input PMBus line 0.

I2C Line 0 SDA_0 Bi-direct PMBus line 0.

I2C Line 1 SCL_1 Input PMBus line 1.

I2C Line 1 SDA_1 Bi-direct PMBus line 1.

SMBALERT# Line 0 ALERT#_0 Output PMBus line 0 interrupt

SMBALERT# Line 1 ALERT#_1 Output PMBus line 1 interrupt

RS485 Line RS_485+ Bi-direct RS485 line +

RS485 Line RS_485- Bi-direct RS485 line -



Conformal Coated

Product



The rectifier can be ordered with conformal coating for additional protection against either humidity or dust born particles. Below

are the basic processes

1. Conformal coating applied to both sides of the main board and control cards. Connector connections are masked to

ensure that the coating does not penetrate connector contacts.

2. CMPD1 conformal coating applied on indicated areas without masking all exposed SMT components, solder joints, open

traces, thru-hole leads and vias on the bottom of the pcb. Overspill on adjacent components is acceptable.

3. Coating material: Liquid HUMISEAL 1A33 POLYURETHANE CONFORMAL COATING. GE COMCODE: 450023185. HUMISEAL

PART NUMBER: 1A33 PB65

4. Minimum 3 mils thickness applied as uniformly as possible

5. Cured fully before sheet metal assembly. Curing process: 11HR @ 88C

6. Conformal coating passes standard IPC-A-610 Class 2



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



SIGNAL

OUTPUT POWER INPUT POWER

SCL_0 MOD_ PRES PFW LOGIC_GRD

RS_485+ UNIT_ADDR 

EARTH

(GND)

SCL_1 OTW Alert#_0 Alert#_1 RS_485- 8V_INT

_OUT

_OUT LINE-2 LINE-1

SDA_0 Margin Enable Reset Ishare Protocol (-

)

(+) (+) (-

)

(Neutral) (HOT)

SDA_1 Fault

5VA

Power_Cap

ON/OFF SHELF_ADDR

Note: Connector is viewed from the rear

positioned

inside the rectifier

Signal pins columns 1 and 2 are

referenced

to V_OUT (–)

Signal pins columns 3 through 6 are

referenced

to Logic GRD

Last to make-first to break shortest pin

Earth

First make-last to break longest pin

implemented

in the mating connector



Mechanical

Outline



Dimensions



351.2

(13.85

in)



101.6mm

(4.00

in)



Top

View



41.4mm

(1.63 in)



Front View Rear View



Front Panel LEDs



Analog Mode I2C Mode RS485 M

ON: Input ok

Blinking: Input out of limits

ON: Output ok

Blinking: Overload



ON: Over-temperature Warning ON: Over-temperature Warning

Blinking: Service ON: Over-temperature Warning



ON: Fault ON: Fault

Blinking: Not communicating



Output

Connector



Mating Connector: right angle PWB mate – all pins: TE 6450572-1, right angle PWB mate except pass-thru input power: TE 6450378-1



A6 A1 P7 P1



Manufacturer part numbers: FCI

51939-568



CP2725AC54TE CPL High Efficiency Rectifier

100-120/200-277VAC input; Default Outputs: ±54VDC @ 2725W, 5VDC @

Data

Sheet



Ordering

Information

Please contact your GE Power Sales Representative for pricing, availability and optional features.

Table 4: Device Codes



Item

Description

Comcode

CP2725AC54TEZ 54VDC @ 50A, 5VDC @ 0.75A, RoHS 6/6 CC109149423

CP2725AC54TEP 54VDC @ 50A, 5VDC @ 0.75A, RoHS 6/6, POE compliant CC109167532

CP2725AC54TEZ-LCC 54VDC @ 50A, 5VDC @ 0.75A, RoHS 6/6, Conformal Coated, Laser Tuned 1600115617A



Accessories



Item

Description

Comcode

Power supply interface board 150037482

Isolated Interface Adapter Kit – interface between a USB port

and the I2C connector on the power supply interface board

150036482



. The site below downloads the GE Digital Power Insight™

software tools, including the cpgui_l. When the download is

complete, icons for the various utilities will appear on the

desktop. Click on cpgui_l.exe to start the program

after the download is complete.

http://apps.geindustrial.com/publibrary/checkout/Software%7

CCPSW-DPI%7Cgeneric



Graphical User Interface Manual; The GUI download created a

directory In that

directory start the DPI_manual.pdf file.



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



www.gecriticalpower.com



GE Critical Power reserves the right to make changes to the product(s) or information contained herein without notice, and no

liability is assumed as a result of their use or application. No rights under any patent accompany the sale of any such

product(s) or information.

