SYNQOR IQ65033QMA10EYF-G

Technical
Specification
IQ65033QMA10
36-75V @ 10 A
3.3 V & 5.0 V
Quarter-Brick ATCA
Input/Output
MGMT Power
Power Interface Module
The IQ65033QMA10 iQor™ Power Interface Module
integrates all features required by the AdvancedTCA
Base Specification into a Quarter-Brick footprint. The
iQor offers industry leading external hold-up capacitor
volumetric density for a compact overall solution. At
a 90V hold‑up capacitor voltage (trimmable 50-95 V),
only 564 µF is required to achieve 8.70ms hold‑up time
at 200Win. The -48 V output voltage is conditioned for
smooth operation through severe input transient events.
The iQor is designed thermally and electrically to drive
high power wide-range-input DC/DC converters such as
the 300 W SynQor PQ60120QEA25. RoHS Compliant see
last page.
Operational Features
IQ65033QMA10 Module
• Input ORing for A & B power feeds (MOSFET-based for
low power dissipation)
• Hot swap control with seamless ride-through of input
voltage transient
• EMI filter meets CISPR 22 Class B when used as directed
(see applications section)
• External hold-up capacitor trimmable from 50-95 V
• Automatic discharge of external hold-up capacitor
• Isolated management power of 3.3 V at 3.6 A and 5.0 V
at 150 mA
• Dual input side enable
• I2C interface data reporting (optional)
Protection Features
• Management power over-voltage protection
• Management power over-current protection
• Main output over-current protection
• Thermal shutdown protects the unit from abnormal
environmental conditions
• Input fuse/feed loss alarm
Safety Features
Mechanical Features
• Industry standard quarter-brick size: 1.45" x 2.3"
(36.8x58.4 mm)
• Overall height of 0.54" (13.7 mm), permits better airflow
and smaller card pitch
• Total weight: 1.2 oz (34 g)
• Flanged pins designed to permit surface mount soldering
(avoid wave solder) using FPiP technique
• External hold-up capacitor footprint much smaller than
other solutions currently available on the market
Product # IQ65033QMA10
Phone 1-888-567-9596
• 2250V, 30 MΩ VRTN_A/B to LOGIC_GND and
SHELF_GND isolation
• UL/cUL 60950-1 recognized (US & Canada), basic
insulation rating
• TUV certified to EN60950-1
• Meets 72/23/EEC and 93/68/EEC directives which
facilitates CE Marking in user’s end product
• Board and plastic components meet UL94V-0
flammability requirements
www.synqor.com
Doc.# 005-IQ5033S Rev. G
05/04/09
Page 1
Input:
Outputs:
Current:
Package:
Technical Specification
MECHANICAL DIAGRAM
2.30
(58.42)
Top View
0.200
(5.08)
0.200
(5.08)
1.45 0.200
(36.83) (5.08)
0.200
(5.08)
0.200
(5.08)
0.225
(5.72)
0.100
(2.54)
0.150 0.150 0.150
(3.81) (3.81) (3.81)
0.950 (24.13)
1
18 17 16 15
14
2
3
12
4
11
5
10
9
6
8
7
2.00
(50.8)
Bottom side
Clearance
0.064 ±0.028
(1.63 ±0.71)
Side View
Overall
Height
0.54 (13.7)
1.45
(36.83)
Load Board
Flanged Pin
See Note 8
NOTES
1) All Pins are 0.040" (1.02 mm) diameter with 0.080" (2.03 mm)
diameter standoff shoulders.
2) Other pin extension lengths available. Recommended pin
length is 0.03" (0.76 mm) greater than the PCB thickness.
3) All Pins: Material - Copper Alloy
Finish - Matte Tin over Nickel plate
4) Undimensioned components are shown for visual reference only.
5) All dimensions in inches (mm)
Tolerances: x.xx +0.02" (x.x +0.5 mm)
x.xxx +0.010" (x.xx +0.25 mm)
6) Weight: 1.2 oz (34 g) typical
7) Workmanship: Meets or exceeds IPC-A-610C Class II
8) The flanged pins are designed to permit surface mount soldering
(allowing to avoid the wave soldering process) through the use of
the flanged pin-in-paste technique.
* Pins 10, 11, and 12 are only available on the full feature version.
See the ordering page for more information.
** Single resistor connected externally to LOGIC_GND selects the three
least significant bits of I2C Address “0101xxx”.
Product # IQ65033QMA10
0.150
(3.81)
13
0.150
(3.81)
See Note 2
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
Phone 1-888-567-9596
Lowest
Component
PIN DESIGNATIONS
Pin No. Name
1
-48V_A
2
-48V_B
3
VRTN_A
4
VRTN_B
5
ENABLE_A
6
ENABLE_B
7
SHELF_GND
8
5.0V
9
3.3V
10
I2C_ADR
11
I2C_DAT
12
I2C_CLK
13
LOGIC_GND
14
ALARM
15
-48V_OUT
16
HU_TRIM
17
VRTN_OUT
18
HU_CAP
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Function
Negative A Feed (Externally Fused)
Negative B Feed (Externally Fused)
Positive A Feed (Externally Fused)
Positive B Feed (Externally Fused)
Enable A Input (Externally Fused)
(Short Pin Tied to VRTN_A on Backplane)
Enable B Input (Externally Fused)
(Short Pin Tied to VRTN_B on Backplane)
Shelf Ground
5.0V (Relative to LOGIC_GND)
3.3V (Relative to LOGIC_GND)
I2C Address Input *
(Connect External Resistor to LOGIC_GND) **
I2C Data (Relative to LOGIC_GND) *
I2C Clock (Relative to LOGIC_GND) *
Logic Ground
Isolated A/B Feed Loss or Open Fuse Alarm
(Relative to LOGIC_GND)
Negative Output to Payload Power Converter
Hold-Up Voltage Trim
(Connect External Resistor to -48V_OUT)
Positive Output to Payload Power Converter
Positive Connection to Hold-Up Capacitor
(Negative Connection to -48V_OUT)
Doc.# 005-IQ5033S Rev. G
05/04/09
Page 2
Input:
Outputs:
Current:
Package:
Technical Specification
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
IQ65033QMA10 ELECTRICAL CHARACTERISTICS
Specifications subject to change without notice. Specifications in bold are guaranteed by design over the temperature range -40º to 125ºC.
Parameter \
Min.
Typ.
Max.
Units Notes & Conditions
ABSOLUTE MAXIMUM RATINGS
Input Voltage
Continuous
-75
V
Limited by internal TVS zener diode
Transient
-100
V
1ms transient, square wave
Reverse Polarity
+75
V
No damage, low current, output diode clamped
Isolation Voltage
(VRTN_A/B to LOGIC_GND)
2250
V
(VRTN_A/B to SHELF_GND)
2250
V
Operating Temperature
-40
100
°C
Subject to thermal derating; see Figures 1 & 3
Storage Temperature
-55
125
°C
Hold-up Capacitor Voltage (Relative to -48V_OUT)
100
V
-48V DUAL FEED INPUT CHARACTERISTICS
Input Voltage Range
-34
-48
-75
V
Subject to the Threshold Protocol used
Operating Current
10
A
25ºC 950 LFM, Vin = -48V; see Figure 1
Disabled Input Current below Turn-Off Threshold
8
10
mA
Enabled No-Load Input Current
21
30
mA
Vin = -48V
Internal Input Filter Capacitance (Not Hot-Swapped)
18
22
µF
Should be precharged by resistors to EARLY_A/B pins
Recommended EARLY_A/B Resistors
100
W
Surge rated 2010 case size (KOA SG73 series or equiv.)
Recommended Input Fuses
15
A
3.3V ISOLATED MANAGEMENT POWER
Startup Delay
Time from ENABLE_A/B to 3.3/5.0Vout
At 36Vin
0.43
0.50
s
At 48Vin
0.31
s
At 75Vin
0.15
0.20
s
Turn-On Rise Time
1
5
20
ms
0% to 90%; see Figure 10
Input Under-Voltage Lockout
Turn-On Voltage Threshold (ATCA)
-33.5
-34.5
-36.0
V
At Mangement Power Converter input; see Figure A
Turn-Off Voltage Threshold (ATCA)
-32.0
-34.0
-35.5
V
“
Turn-On Voltage Threshold (NEDS)
-33.5
-34.5
-36.0
V
“
Turn-Off Voltage Threshold (NEDS)
-32.0
-34.0
-35.5
V
“
Turn-On Voltage Threshold (ETSI)
-25.5
-26.5
-28.0
V
“ ; overriden by enable
Turn-Off Voltage Threshold (ETSI)
-24.0
-26.0
-27.5
V
“ ; overriden by enable
Total Output Voltage Range
3.170
3.350
3.430
V
Including line, load, sample, life, and temp
Output Voltage Ripple and Noise
See Figure 12
Peak-to-Peak
40
75
mV
Full load, 10µF ceramic, 500MHz bandwidth
RMS
16
30
mV
“
Operating Output Current Range
0
3.6
A
Subject to thermal derating; see Figures 1 & 3
Output DC Current-Limit Inception
3.9
5.4
6.9
A
Current Limit Shutdown Voltage
1.5
V
Initiates hiccup mode
Hiccup Mode Restart Time
130
ms
Vin = -48V
Back-Drive Current
10
mA
Negative current drawn from output source
Maximum Output Capacitance
1000
µF
Switching Frequency
200
220
240
kHz
Management power converter
Over-Voltage Protection Setpoint
4.10
4.33
4.55
V
5.0V POWER (Derived From 3.3V Converter)
Total Output Voltage Range
4.80 1
5.00
5.20
V
Including line, load, sample, life, and temp
Operating Output Current Range
0
150
mA
Short Circuit Current
400
mA
Independent Thermal Protection
Back-Drive Current
1
mA
Negative current drawn from output source
Maximum Output Capacitance
1000
µF
TEMPERATURE LIMITS FOR POWER DERATING CURVES
Semiconductor Junction Temperature
125
°C
Package rated to 150°C
Board Temperature
125
°C
UL rated max operating temp 130°C
Transformer Temperature
125
°C
See Figure 3 for derating curve
Product # IQ65033QMA10
Phone 1-888-567-9596
www.synqor.com
Doc.# 005-IQ5033S Rev. G
05/04/09
Page 3
Input:
Outputs:
Current:
Package:
Technical Specification
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
IQ65033QMA10 ELECTRICAL CHARACTERISTICS (Continued)
Specifications subject to change without notice. Specifications in bold are guaranteed by design over the temperature range -40º to 125ºC.
Parameter \
Min.
Typ.
Max.
Units Notes & Conditions
DUAL ENABLE INPUT CHARACTERISTICS
ENABLE_A/B Threshold
V
ATCA 26.0
28.5
31.0
V
At input feed voltage -48V_A/B; see Figure A
NEDS (ON\OFF)
40.0\36.0 42.5\39.0 45.0\42.0
V
“
ETSI 32.0
34.0
36.0
V
“
Current Drain per Enable Pin (Vin = -75V)
0.36
mA
-48V OUTPUT
Efficiency
No load on 3.3V/5.0V outputs, Vin = -48V
300W Output Power
97.7
98.2
200W Output Power
98.0
98.5
Equivalent Resistance From Input Feed
120
200
mW
Recommended External Output Filter Capacitance
80
100
270
µF
See Note 2
Hot-Swap Startup Ramp dV/dt
150
200
250
V/s
Output Voltage Delay
250
650
ms
No load; depends on external cap.; see Figure 5
Input Current Limit (Turns Off Hot-Swap Momentarily)
15
17.5
20
A
Hold-up still active
Input dV/dt Limit (Turns Off Hot-Swap Momentarily)
40
V/ms
“
Short Circuit Duration to Initiate Hiccup Mode
2
ms
Restart Time in Hiccup Mode
1.8
2.0
2.2
s
INPUT ORING
ORing MOSFET Turn On Current
0.4
1.0
2.4
A
ORing MOSFET Turn Off Current
0.1
0.4
1.1
A
ORing MOSFET Current Hysteresis
0.3
0.6
1.3
A
Turn On Time
600
µs
Turn Off Time
0.25
µs
HOLD-UP CAPACITOR INTERFACE
Hold-up Capacitor Trim Range
50
90
95
V
Can be set either above or below input voltage
Hold-up Capacitor Charge Accuracy
87.2
90.0
92.8
V
2.49kΩ external trim resistance, 1% 100ppm/ºC
External Hold-up Voltage Trim Resistor Power Dissipation
160
µW
Hold-up Capacitor Charge Current
40
mA
Switching Frequency
405
450
495
KHz Hold-up power converter
-48V_OUT Threshold
See Note 3
To Arm Hold-up (ATCA/NEDS options)
-36.9
-38.9
-40.9
V
At VRTN_OUT w.r.t. -48V_OUT; see Figure A
To Initiate Hold-up (ATCA/NEDS)
-36.4
-38.5
-40.4
V
“
To Arm Hold-up Connect (ETSI)
-32.4
-34.5
-36.4
V
“
To Initiate Hold-up Connect (ETSI)
-32.4
-34.5
-36.4
V
“
dV/dt on Hold-up Connect
80
V/ms
Duration of Hold-up Connect
0.1
s
See Note 4
Delay Before Hold-up Connect is (Re)Armed
2
s
48V output still enabled
Hold-up Capacitor Discharge Resistance
1.55
1.65
1.75
kΩ
Maximum Hold-up Capacitance
3300
µF
Yields 55ms (200 W at 90 V cap charge)
ISOLATED ALARM OUTPUT (Alarm = HiZ)5
Input A/B Feed Voltage Alarm Threshold
36.4
38.4
40.4
V
At input feed voltage -48V_A/B; see Figure A
Open Circuit Voltage
40
V
On-State Voltage
0.2
0.4
V
At 50mA
On-State Transistor Collector Current
50
mA
Off-State Transistor Collector Current
1
µA
Note
Note
Note
Note
Note
1:
2:
3:
4:
5:
If the 5.0 V load current exceeds 100 mA, up to 200 mV of additional voltage drop is possible on the 5.0 V output.
Maximum DC load at startup is 50 mA. Full load can be applied 700 ms after enable or 400 ms after the management power is up and running.
Hold-up operation with Vin < 43 V not required by ATCA specification.
48 V output does not recover after hold-up event unless input is above Arm Hold-up threshold.
Does not inhibit 48 V output and is non-latching.
Product # IQ65033QMA10
Phone 1-888-567-9596
www.synqor.com
Doc.# 005-IQ5033S Rev. G
05/04/09
Page 4
Input:
Outputs:
Current:
Package:
Technical Specification
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
IQ65033QMA10 ELECTRICAL CHARACTERISTICS (Continued)
Specifications subject to change without notice. Specifications in bold are guaranteed by design over the temperature range -40º to 125ºC.
Parameter P
Min.
Typ.
Max.
I2C DATA REPORTING INTERFACE
Maximum Clock Rate
100
400
Measurement Error
Feed Voltage A/B
+3
Holdup Voltage
+3
-48V_OUT Current
+3
Temperature
+3
OVER-TEMPERATURE PROTECTION
Shutdown Point
135
Restart Hysteresis
10
RELIABILITY CHARACTERISTICS
Calculated MTBF (Telcordia)
3.6
Calculated MTBF (MIL-217)
3.27
Field Demonstrated MTBF
Units Notes & Conditions
kHz
Clock stretching happens at the maximum rate
%
%
%
°C
°C
°C
Does not shut down Management Power
Automatic restart
106 Hrs. TR-NWT-000332; 80% load,300LFM, 40oC Ta
106 Hrs. MIL-HDBK-217F; 80% load, 300LFM, 40oC Ta
106 Hrs. See website for details
STANDARDS COMPLIANCE
Parameter P
Notes
UL/cUL 60950-1 EN60950-1 72/23/EEC
93/68/EEC
Needle Flame Test (IEC 695-2-2)
IEC 61000-4-2
GR-1089-CORE
Telcordia (Bellcore) GR-513
File # E194341, Basic insulation & pollution degree 2
Certified by TUV
STANDARDS COMPLIANCE
Test on entire assembly; board & plastic components UL94V-0 compliant
ESD test, 8kV - NP, 15kV air - NP (Normal Performance)
Section 7 - electrical safety, Section 9 - bonding/grounding
• An external input fuse must always be used to meet these safety requirements. Contact SynQor for official safety
certificates on new releases or download from the SynQor website.
QUALIFICATION TESTING
Parameter P
QUALIFICATION TESTING
Life Test
Vibration
Mechanical Shock
Temperature Cycling
Power/Thermal Cycling
Design Marginality
Humidity
Solderability
# Units
32
5
5
10
5
5
5
15 pins
Test Conditions
95% rated Vin and load, units at derating point, 1000 hours
10-55Hz sweep, 0.060” total excursion,1 min./sweep, 120 sweeps for 3 axes
100g minimum, 2 drops in x and y axis, 1 drop in z axis
-40°C to 100°C, unit temp. ramp 15°C/min., 500 cycles
Toperating = min to max, Vin = min to max, full load, 100 cycles
Tmin-10°C to Tmax+10°C, 5°C steps, Vin = min to max, 0-105% load
85°C, 85% RH, 1000 hours, 2 minutes on and 6 hours off
MIL-STD-883, method 2003
• Extensive characterization testing of all SynQor products and manufacturing processes is performed to ensure that we supply
robust, reliable product. Contact the factory for official product family qualification documents.
Product # IQ65033QMA10
Phone 1-888-567-9596
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Doc.# 005-IQ5033S Rev. G
05/04/09
Page 5
Input:
Outputs:
Current:
Package:
Technical Specification
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
10
9
Iout (A)
8
7
6
400 LFM (2.0 m/s)
5
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
4
100 LFM (0.5 m/s)
3
10
25
40
55
70
85
Ambient Air Temperature (°C)
Figure 1: -48V output (maximum power) derating curves vs. ambient air temperature for airflow rates of 100 LFM through 400 LFM with air flowing across
the converter from pin 7 to pin 1 (48 Vin, 3.3V mgmt power output @ 1.5 A).
Figure 2: Thermal plot of converter at 6.2A load current from -48V output (298W) with 55°C air flowing at the rate of 200 LFM. Air is flowing
across the converter from pin 7 to pin 1 (48 Vin, 3.3V output @ 1.5 A).
4.0
3.5
Iout (A)
3.0
2.5
2.0
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
1.5
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
1.0
10
25
40
55
70
85
Ambient Air Temperature (°C)
Figure 3: 3.3V output (maximum power) derating curves vs. ambient air temperature for airflow rates of 100 LFM through 400 LFM with air flowing across
the converter from pin 7 to pin 1 (48 Vin, main output power output @ 4 A).
Figure 4: Thermal plot of converter at 2.9A load current from 3.3V output (9.6W) with 55°C air flowing at the rate of 200 LFM. Air is flowing
across the converter from pin 7 to pin 1 (48 Vin, -48V output @ 4 A).
Figure 5: 48V hot-swap turn-on transient (100uF electrolytic filter
capacitor CF). Top trace: VRTN_OUT w.r.t. -48V_OUT (20V/div),
Bottom trace: Input Feed Current (2A/div).
Figure 6: 8.70ms zero volt transient (564uF electrolytic hold-up capacitor CH, 100uF electrolytic filter capacitor CF). Ch 1: Input Feed A/B
Voltage (20V/div). Ch 2: VRTN_OUT w.r.t. -48V_OUT (20V/div). Ch 3:
HU_CAP w.r.t. -48V_OUT (20V/div). Ch 4: 3.3V_OUT (200mV/div).
Product # IQ65033QMA10
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Doc.# 005-IQ5033S Rev. G
05/04/09
Page 6
Input:
Outputs:
Current:
Package:
Technical Specification
Figure 7: Instantaneous input transient from 48V Feed A to 60V Feed B.
Ch 1: Input Feed A Voltage (20V/div). Ch 2: Input Feed B Voltage (20V/
div). Ch 3: VRTN_OUT w.r.t. -48V_OUT (20V/div). Ch 4: 3.3V_OUT
(200mV/div).
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
Figure 8: Inductive Switching event on Feed A from 48V to 0V to TVS
Zener clamping voltage. No load on -48V output. Ch1: Input Feed A
Voltage (20V/div). Ch3: VRTN_OUT w.r.t. -48V_OUT (20V/div). Ch 4:
3.3V_OUT (50mV/div).
8
Power Dissipation (W)
7
6
5
4
3
2
36 Vin
48 Vin
1
75 Vin
0
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
Load Current (A)
Figure 9: Power dissipation vs. 3.3V load current with hot-swap switch
enabled.
Figure 10: Management Power turn on transient at 50% load (4ms/div).
Load capacitance: 10uF ceramic capacitor. Ch 2: 3.3Vout (1V/div). Ch
3: 5.0Vout (1V/div).
Figure 11: 3.3Vout response to a step-change in load current (50%75%-50% of Iout(max): dI/dt = 1A/us). Load capacitance: 10uF ceramic
capacitor. Top trace: 3.3Vout (500mV/div). Bottom trace: Iout (1A/
div).
Figure 12: 3.3Vout ripple at nominal input voltage at rated load current
(20mV/div). Load capacitance: 10uF ceramic capacitor. Bandwidth:
500MHz.
Product # IQ65033QMA10
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Doc.# 005-IQ5033S Rev. G
05/04/09
Page 7
Input:
Outputs:
Current:
Package:
Technical Specification
5
6
ENABLE_A
HU_CAP
18
ENABLE_B
VRTN_A
3
Temp
sense
Enable Logic
FET
control
4
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
E
dV/dt
sense
F
A
Hold-up
connect control
circuits
VRTN_B
VRTN_OUT
17
FET
control
E
Hot Swap
Control Logic
B
F
-48_A
EMI Filter
1
C
Currentcontrolled holdup charging
converter
FET
control
HU_TRIM
16
-48V_OUT
15
-48_B
2
D
FET
control
Management
Power
converter
A
F
10
11
12
14
Isolation barrier
LOGIC_GND
E
ALARM
Monitoring
circuits
D
I2C Clock
SHELF_GND
I2C Add.
7
C
I2C Data
B
Discharge
3.3V
8
9
5.0 V
13
Figure A: Internal Block Diagram
FEATURE DESCRIPTIONS
Input ORing MOSFETs: ORing of dual -48V feeds is provided
by four MOSFETs, which are individually controlled so as to operate as an ideal diode (see Figure A). If there is an input feed short
of any kind, a control circuit will detect reverse current and turn
off the MOSFET in 250ns (typ.), to avoid disturbing the other feed
voltage. At zero current, the MOSFET is guaranteed to be off. In
the case of a fuse failure, this triggers the ALARM output, due to an
apparent input feed loss. Current hysteresis prevents limit cycling
around the transition point between body diode and MOSFET
conduction.
ALARM Output: The ALARM pin gives an external indication
of a fault condition. It is an isolated and buffered open-collector
output, which is normally pulled low. In the presence of an input
feed loss (which can be caused by a fuse failure), the ALARM output will be tri-stated.
Product # IQ65033QMA10
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External Input Fuse Failure Detection: At zero current, the
input ORing MOSFETs are guaranteed to be off. In the case of a
fuse failure, an on-board bleed resistor pulls the input feed voltage
down. This triggers the ALARM output due to an apparent input
feed loss. There are two main down-sides to this approach. First,
there is no way to distinguish between a feed loss and a fuse failure. Second, an enable fuse loss is not detected, since the enables
are diode OR’d.
The full featured version of the iQor offers additional data reporting that makes full fuse detection possible. Among other data,
each feed voltage and each enable voltage is reported through
the I2C port. These voltages can be compared with the voltages
reported by the shelf manager to determine whether any board
fuse is blown.
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Doc.# 005-IQ5033S Rev. G
05/04/09
Page 8
Input:
Outputs:
Current:
Package:
Technical Specification
Input Enable: The ENABLE_A/B signals connect to VRTN_A/B
on the backplane via the shortest pins in the zone 1 connector.
They are the last pins to mate during board insertion, and the
first to disconnect during board extraction. The ENABLE_A and
ENABLE_B signals are diode-ORed together which lets either signal enable the module. Whenever both ENABLE pins are open,
the hot-swap switch is opened. This prevents -48V output power
from being drawn though the EARLY pre-charge resistors.
The ENABLE signals also control the management power. On
board insertion, the management power remains off until at least
one of ENABLE_A/B is connected. On board extraction, the
management power is disabled at the end of the 100ms hold-up
period, and remains off until ENABLE_A/B is reconnected. This
prevents the IPMI controller from reading an invalid hardware
address when a board is partially inserted. Management power
flows through the EARLY pre-charge resistors for a maximum of
100ms, which provides a margin similar to the pre-charge event
in terms of resistor safe-operating-area.
EARLY Precharge Resistors: The EARLY_A/B signals connect
to the longest pins in the zone 1 power connector, and therefore
first to mate during board insertion. External resistors connected
between these signals and VRTN_A/B allow the relatively small
EMI filter capacitance to be pre-charged before the main power
pins make contact. A 100W surge rated 2010 case size resistor
is recommended (KOA SG73 series or equivalent).
Hot Swap - Thermal Shutdown: To protect the unit from
damage in an abnormal thermal environment, the hot-swap switch
will be disabled when the thermal sensor temperature rises above
the turn-off threshold. The switch will be automatically enabled
again when the temperature goes below the turn-on threshold.
The management power remains on during an over-temperature
condition.
The full featured version of the iQor reports the actual temperature
through the I2C port.
Hot Swap - Over-Current Protection: If the -48V output
current rises above the current limit threshold, the hot-swap switch
will be disabled, and will immediately enter another soft-start
sequence. If an output short is detected, the hot-swap switch
will be disabled and will enter a hiccup mode of operation with
automatic restart.
The full featured version of the iQor reports actual output current
through the I2C port.
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
The iQor unit conditions the -48V output, providing for seamless ride-through of input voltage transients. If the positive dV/
dt of the input voltage is too high, the hot-swap switch will be
disabled and will immediately enter another soft-start sequence.
This limits the dV/dt seen on the -48V output, which prevents the
12V payload power converter from having such a large glitch
on its output that it shuts down. The -48V output hold-up function
remains active throughout, in case the hot-swap switch is forced
off for too long.
Passive Transient Suppression: Each input feed has a dedicated internal bidirectional TVS zener diode, rated for a minimum
clamp voltage of 77.8V at 1mA. A TVS diode short due to electrical overstress will not disable the iQor module: a fuse will open,
and the module can continue to run from the other feed.
External Hold-up Capacitor Charge: A current controlled
DC-DC converter charges the external hold-up capacitor to a voltage of 50V-95V, set by an external resistor. The charge voltage
can range either above or below the input feed voltage. Constant
current charging takes place whenever the hot-swap switch is
enabled.
Hold-up Capacitor Connect: When the hot-swap switch is
enabled, 2 seconds are allocated to charge the hold-up capacitor. After this time, a comparator is armed, which connects the
hold-up capacitor to the -48V output should the output ever drop
below the given connect threshold. A current limit circuit protects
against damage during a short circuit condition. A dV/dt limit circuit regulates the hold-up connect switch turn-on speed. When the
comparator is tripped, the hold-up connect switch remains closed
for 100ms, is off for 2 seconds to allow the hold-up capacitor to
recharge, and then is automatically rearmed (if the output voltage
is above the given arm threshold).
Hold-up Capacitor Discharge: Whenever the hot-swap
switch is disabled, an internal resistor bank is connected across
the hold-up capacitor. This is intended to reduce the voltage on
the hold-up capacitor below 60V within 1 second.
Management Power: An isolated management power
converter delivers both 3.3V and a low power 5.0V relative
to LOGIC_GND. Over-current protection operates in constant
current with a hiccup mode if the output voltage drops too far.
Output over-voltage circuitry is included with a redundant reference and optocoupler.
Hot Swap - Transient Suppression: Input transient events
can occur if there is a short on an adjacent board or backplane.
The short builds up a large current in the wiring inductance,
and when a fuse blows, the voltage behind the fuse spikes very
quickly. This can cause a loss of redundancy since many other
boards could be exposed to this spike.
Product # IQ65033QMA10
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Doc.# 005-IQ5033S Rev. G
05/04/09
Page 9
Input:
Outputs:
Current:
Package:
Technical Specification
Hot Swap – Shutdown Timing: In the event of a sudden loss
of input voltage (see Figure B), a hold-up event will be triggered.
When the output voltage (plus a diode drop for the hot-swap body
diode) decays to the management power under-voltage turn-off
threshold, the main -48V output and the 3.3V/5.0V outputs will
shut down simultaneously.
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
In the event of a gradual loss of input voltage (see Figure C), the
main -48V output will shut down 100ms after the beginning of
the hold-up event. The -48V output will enter a hiccup mode of
operation for input voltages below the Hold-up Arm Threshold.
Management power will continue to run until the input voltage
(plus 0V to 1.2V for the ORing MOSFETs) decays to the management power under-voltage turn-off threshold.
48V
Input voltage
0
Holdup time, tH
Holdup event
48V
39 V
typ.
(Depends
on version)
Payload output 48V
0
34.6 V
typ.
3.3V
Management power
0
Alarm
(Pull-up voltage lost)
0
Figure B: Sudden Loss of Input Power
48V
Higher of A/B input feed voltages
VRTN A/B - (-48V_A/B)
38.9 V
typ.
38.4 V
typ.
34.0
(Depends
on version)
0
Holdup event
48V
-48V output voltage
VRTNOUT - (-48V_OUT)
38.5 V
typical
(Depends
on version)
100ms
Output is off after
delay if input
voltage doesn’t
recover above
38.9V typ.
0
3.3V
0
Management power turned
off at higher of ENABLE
threshold or MP UVLO .
Management power output
(3.3V) - LOGIC_GND
Alarm - (LOGIC_GND)
(Pullup voltage lost)
Figure C: Gradual Loss of Input Power
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05/04/09
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Input:
Outputs:
Current:
Package:
Technical Specification
EXTERNAL HOLD-UP CAPACITOR SELECTION
100
2t P
CH = H H
V²H – V²U
Equation A
Typically a strong function of VH (see Figure D).
The ATCA specification requirement is 8.70ms (see Figure E).
Where:
VH = hold-up capacitor charge voltage.
VU = minimum operating voltage on the 48V output; the greater
of the under-voltage lockout threshold of the payload power
converter, and the under-voltage lockout threshold of the
management power converter.
tH = time from when the highest input feed voltage drops below
VF, to the time when the highest input feed voltage rises
above VU.
VF = voltage at which the hold-up capacitor is engaged.
PH = power drawn from the hold-up capacitor, the sum of the input
power of the payload power converter, and the input power
of the 3.3V mgmt power converter (see Figure 9):
P
Equation B
PH = OUT 12V + PIN 3.3V
η12V
Hold-up Time (ms)
70
60
50
43.0V
41.0V
40
36.0V
30
20
10
0
0
1
2
3
4
5
6
7
8
9
10
8.70ms
Time (ms)
Figure E: The PICMG 3.0 R2.0 AdvancedTCA Base Specification
requires continuous operation through a zero-volt transient, lasting 5ms
(Section 4.1.2.2). However, this is not a square wave: the voltage starts
at a minimum amplitude of -43V, falls at 50V/ms, remains at 0V for
5ms, and then rises at 12.5V/ms. At the worst case values of the hold-up
connect threshold and the management power under-voltage lockout
threshold, the required hold-up time is 8.70ms.
Operating electrolytic capacitors near their voltage rating does
not significantly affect their reliability, as it does with tantalum
or ceramic type capacitors. The operating life of electrolytic
capacitors is primarily determined by the capacitor internal
temperature. The capacitor lifetime roughly doubles for every
10ºC reduction in internal temperature. SynQor recommends
running 100V rated electrolytic capacitors at 90V, which
dramatically increases hold-up time for a given capacitor volume
(see Figure D). A built-in circuit automatically discharges the
hold‑up capacitor when the input voltage is removed.
PH=200W
CF=100µF
VI=- 43V
15
10
5
80
EXTERNAL HOLD-UP CAPACITOR VOLTAGE RATING
POUT12V = output power delivered by the payload converter.
η12V = efficiency of the 12V payload converter.
PIN.3.3V = 3.3V input management converter power.
20
90
Input Feed Voltage (V)
CH is the hold-up capacitance (electrolytic capacitors typically
have a ±20% tolerance):
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
90V
80V
70V
0
300
400
500
600
700
800
900
1000
Hold-up Capacitance (µF)
Figure D: Hold-up Time (ms) vs. Hold-up Capacitance (µF) at
Hold-up Charge Voltages of 70V, 80V, and 90V (see Equation A).
The AdvancedTCA hold-up time requirement is at most 8.70ms (solid
horizontal line). The capacitor tolerance is not factored into this result.
Error bars indicate the worst case range of hold-up time for a given
hold-up capacitance.
Product # IQ65033QMA10
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05/04/09
Page 11
Input:
Outputs:
Current:
Package:
Technical Specification
EXTERNAL HOLD-UP TRIM RESISTOR SELECTION
Rtrim =
(
500,000
– 10,000
VHU – 50.0
)
Ω
Equation C
External Hold-up Trim Resistance ( Ω )
100000
Rtrim is the external hold-up trim resistance for a given desired nominal hold-up capacitor charge voltage (VHU) (see Figure F):
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
10000
1000
50
60
70
80
90
100
Hold-up Charge Voltage (V)
Figure F: Plot of Equation C, used to choose the external trim resistor
value based on the desired Hold-up Capacitor charge voltage. Error
bars indicate the worst case range of charge voltage for a given external trim resistor value (assumes 1%, 100ppm for external trim resistor
tolerance). Worst case calculation over temp range -40ºC to 125ºC.
* Shield plane should extend
under payload power
converter
Shield Plane*
Payload
Power
Converter
R trim
100µF
100V
-48V_B
VRTN_A
RTN 48V B
VRTN_B
Enable A
ENABLE_A
Enable B
ENABLE_B
SHELF_GND
Shelf Gnd
SynQor
iQor
ATCA
Power Input Module
I2C interface on fullfeatured version only
Alarm
ALARM
LOGIC_GND
100Ohms
RTN 48V A
PQ60120QEA25
I2C CLOCK
3.3kOhms
Early B
-48V_A
(from IPM)
-48V_OUT
-48V B
HU_TRIM
100Ohms
VRTN_OUT
Early A
HU_CAP
-48V A
12V
10nF
CH
10nF
10Ohms
Holdup capacitor
I2C DATA
I2C ADDRESS
3.3 V
3.3V to IPM
5.0V
Blue LED bias
Figure G: Application Diagram
Product # IQ65033QMA10
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05/04/09
Page 12
Input:
Outputs:
Current:
Package:
Technical Specification
full feature application Notes
I2C Data Reporting Interface: Available on the full feature
version of the module, the iQor I2C Serial Interface monitors 5
analog parameters and 6 status bits. The actual analog parameter
values are calculated by multiplying by the specified scaling
factors (see Table 1). The status bits are interpreted in Table 2.
The initial value of all registers is zero. Data in the registers begins
updating 300 ms after management power startup, and continues
updating at approximately 100 ms intervals during steady-state
operation. All registers are updated simulatneously.
Data_Pointer
Parameter
Value
Description
Scaling
Factor
Status Bits
Digital Signals
(see Table 2)
N/A
1Fh
HU_CAP
Voltage between HU_
CAP and -48V_OUT
0.398 V/bit
21h
-48V_Current
-48V Output Current
0.094 A/bit
22h
-48V_A
Voltage between
VRTN_A and -48V_A
0.325 V/bit
23h
-48V_B
Voltage between
VRTN_B and -48V_B
0.325 V/bit
28h
Temperature
Average Unit
Temperature
(1.961 ºC/bit)
– 50 ºC
1Eh
Table 1: Internal register memory map.
Bit
Name
Description
Value
0
ENABLE_A
Enable A Signal
State
0
EN_A is Disabled
1
EN_A is Enabled
1
ENABLE_B
Enable B Signal
State
0
EN_B is Disabled
1
EN_B is Enabled
2
ALARM
Alarm Signal
State
0
Primary side Alarm is not SET
1
Primary side Alarm is SET
3
N/A
Reserved
0
HOLDUP
Holdup Switch
State
Holdup Cap is not connected
to -48V Out
1
Holdup Cap is connected
to -48V Out
4
Translation
I2C Protocol: Reading from any internal register of the iQor
monitor requires that an internal (pseudo) register, Data_Pointer,
be initialized prior to reading (see Figure H).
Data_Pointer is write-only. It is written from the second byte of
any I2C WRITE message (the first byte is the 7 bit I2C Address
and the R√W bit). Subsequent data bytes in a WRITE message
(3rd Byte and beyond) only increment Data_Pointer.
Any READ message will return the value of the internal register
referenced by Data_Pointer and increments Data_Pointer by
one. For instance, if the master acknowledges (AK), the next
internal register referenced by Data_Pointer will be returned
and Data_Pointer will be incremented by one. This process is
repeated until the master does not acknowledge (NACK) and
issues a STOP bit.
Data_Pointer is an 8bit value. It is initialized to 00h at reset, and
after reaching FFh, it will not overflow.
Writing to registers not defined in Table 1 has no effect. Reading
from these undefined registers will return 00h. In both cases
Data_Pointer is incremented.
Figure H: Typical I2C read transmission. Note: S = START, W =
WRITE, R = READ, AK = acknowledged, NACK = NOT acknowledged, P = STOP. Clear boxes originate in the I2C Master and
shaded boxes originate in the I2C Slave.
Example from the point of view of the I2C Master:
5
HOTSWAP
Hotswap Switch
State
0
Hotswap switch is OFF
1
Hotswap switch is ON
-48V Output
Under-Voltage
Alarm
0
6
VOUT_
LOW
Output voltage is below
threshold
1
Output voltage is above
threshold
N/A
Reserved
7
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
1) START transmission.
2) Send 56h (addresses unit for writing, given address 56h was
selected as shown in Table 4).
3) Send 22h (loads 22h into Data_Pointer).
4) STOP transmission.
5) START next transmission.
6) Send 57h (addresses unit for reading).
7) Unit will respond with the value of -48V_A (register 22h as
shown in Table 1).
8) ACK (Data_Pointer is automatically incremented to 23h).
9) Unit will respond with the value of -48V_B (register 23h).
10) NACK.
11) Stop Transmission.
Table 2: The status byte represents 6 different digital signals and
their digital state. Note: 1) Bit0 ⇒ LSb, Bit7 ⇒ MSb.
Product # IQ65033QMA10
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Input:
Outputs:
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Package:
Technical Specification
I2C Address structure:
7 bit I2C Address + R√W bit
Four bits are fixed (0101), three bits (xyz) are variable, and the
least-significant bit is the read/write bit.
8 bit I C Address
I2C Address selection: The three bits (xyz) of the I2C Address
are set with a single external resistor from the I2C_ADR (pin 10)
to LOGIC_GND (pin 13). The 8 possible addresses are shown in
Table 4 with the respective resistance values.
External programming resistances
for I2C address selection
2
0101
xyz*
R√W
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
I2C address for
write (R√W = 0)
xyz from Table 3
R (W)
5Eh
111
Open
5Ch
110
100000
5Ah
101
40200
58h
100
20000
56h
011
10000
54h
010
4020
52h
001
2000
50h
000
Short
Table 3: I2C address structure.
Table 4: I2C address selection.
Product # IQ65033QMA10
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Input:
Outputs:
Current:
Package:
Technical Specification
36-75 V
5.0 V/ 3.3 V
10 A
Quarter-brick
PART NUMBERING SYSTEM
ORDERING INFORMATION
The part numbering system for SynQor’s dc-dc converters
follows the format shown in the example below.
The tables below show the valid model numbers and ordering
options for converters in this product family. When ordering
SynQor converters, please ensure that you use the complete
15 character part number consisting of the 12 character base
part number and the additional 3 characters for options.
Add “-G” to the model number for 6/6 RoHS compliance.
IQ 6 5 03 3Q MA 1 0 S N S -G
6/6 RoHS
Options
(see
Ordering Information)
Output Current
Model Number
Input
Voltage
MGMT
Power
IQ65033QMA10xyz-G
36 - 75 V
5.0 V &
3.3 V
Thermal Design
Performance Level
Package Size
36-75V Input/
Output
Current
10 A
Output Voltage
Input Voltage
Product Family
The first 12 characters comprise the base part number and
the last 3 characters indicate available options. The “-G”
suffix indicates 6/6 RoHS compliance.
The following options must be included in place of the x y z
spaces in the model numbers listed above.
Options Description: x y z
Application Notes
A variety of application notes and technical white papers can
be downloaded in pdf format from our website.
RoHS Compliance: The EU led RoHS (Restriction of Hazardous
Substances) Directive bans the use of Lead, Cadmium, Hexavalent
Chromium, Mercury, Polybrominated Biphenyls (PBB), and
Polybrominated Diphenyl Ether (PBDE) in Electrical and Electronic
Equipment. This SynQor product is 6/6 RoHS compliant. For
more information please refer to SynQor’s RoHS addendum
available at our RoHS Compliance / Lead Free Initiative web
page or e-mail us at [email protected].
Threshold Protocols
Pin Style
Feature Set
S - Standard (ATCA)
N - NEDS
E - ETSI
K - 0.110"
N - 0.145"
R - 0.180"
Y - 0.250"
S - Standard
F - Full Feature
Not all combinations make valid part numbers, please contact
SynQor for availability. See the Product Summary web page for
more options.
PATENTS
SynQor holds the following patents, one or more of which
might apply to this product:
5,999,417
6,594,159
6,927,987
7,119,524
6,222,742
6,731,520
7,050,309
7,269,034
6,545,890
6,894,468
7,072,190
7,272,021
6,577,109
6,896,526
7,085,146
7,272,023
Contact SynQor for further information:
Phone:
Toll Free:
Fax:
E-mail:
Web:
Address:
Product # IQ65033QMA10
978-849-0600
888-567-9596
978-849-0602
[email protected]
www.synqor.com
155 Swanson Road
Boxborough, MA 01719
USA
Phone 1-888-567-9596
Warranty
SynQor offers a three (3) year limited warranty. Complete warranty information is listed on our website or is available upon request from SynQor.
Information furnished by SynQor is believed to be accurate and reliable.
However, no responsibility is assumed by SynQor for its use, nor for any
infringements of patents or other rights of third parties which may result
from its use. No license is granted by implication or otherwise under any
patent or patent rights of SynQor.
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Doc.# 005-IQ5033S Rev. G
05/04/09
Page 15