BCM4414XD1E5135YZZ_18 [VICOR]
Isolated Fixed-Ratio DC-DC Converter;型号: | BCM4414XD1E5135YZZ_18 |
厂家: | VICOR CORPORATION |
描述: | Isolated Fixed-Ratio DC-DC Converter |
文件: | 总43页 (文件大小:1493K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
BCM® in a VIA Package
Bus Converter
BCM4414xD1E5135yzz
S
®
C
NRTL US
Isolated Fixed-Ratio DC-DC Converter
Features & Benefits
Product Ratings
• Up to 35A continuous low voltage side current
• Fixed transformation ratio (K) of 1/8
• Up to 797W/in3 power density
• 97.7% peak efficiency
VHI = 400V (260 – 410V)
ILO = up to 35A
K = 1/8
VLO = 50V (32.5 – 51.3V)
(no load)
Product Description
• Built-in EMI filtering and inrush limiting circuit
• Parallel operation for multi-kW arrays
• OV, OC, UV, short circuit and thermal protection
• 4414 package
The BCM4414xD1E5135yzz in a VIA package is a high efficiency
Bus Converter, operating from a 260 to 410VDC high voltage bus to
deliver an isolated 32.5 to 51.3VDC unregulated, low voltage.
This unique ultra-low profile module incorporates DC-DC
conversion, integrated filtering and PMBus™ [1] commands and
controls in a chassis or PCB mount form factor.
• High MTBF
• Thermally-enhanced VIA package
• PMBus™ management interface
• Suitable for Hot-Swap applications
The BCM offers low noise, fast transient response and industry
leading efficiency and power density. A low voltage side referenced
PMBus™ compatible telemetry and control interface provides
access to the BCM’s configuration, fault monitoring and other
telemetry functions.
Typical Applications
Leveraging the thermal and density benefits of Vicor’s VIA
packaging technology, the BCM module offers flexible thermal
management options with very low top and bottom side
thermal impedances.
• 380VDC Power Distribution
• Information and Communication
Technology (ICT) Equipment
When combined with downstream Vicor DC-DC conversion
components and regulators, the BCM allows the Power Design
Engineer to employ a simple, low-profile design, which will
differentiate the end system without compromising on cost or
performance metrics.
• High-End Computing Systems
• Automated Test Equipment
• Industrial Systems
• High Density Energy Systems
• Transportation
• Green Buildings and Microgrids
Size:
4.35 x 1.40 x 0.37 in
[110.55 x 35.54 x 9.40mm]
Part Ordering Information
High
Side
Voltage
Range
Ratio
Max
High
Side
Max
Low
Side
Max
Low
Side
Product
Function
Package
Length
Package
Width
Package
Type
Product Grade
(Case Temperature)
Option Field
Voltage
Voltage Current
BCM
44
14
x
D1
E
51 35
y
zz
BCM =
Bus Converter
Module
02 = Chassis/PMBus
06 = Short Pin/PMBus
10 = Long Pin/PMBus
Length in
Width in
B = Board VIA
C = –20 to 100°C [a]
T = –40 to 100°C [a]
Internal Reference
Inches x 10 Inches x 10 V = Chassis VIA
[a] High temperature current derating may apply; See Figure 1, specified thermal operating area.
BCM® in a VIA Package
Page 1 of 43
Rev 1.7
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BCM4414xD1E5135yzz
Typical Applications
3 Phase AIM
BCMin a VIA package
+
-
+HI
-HI
+LO
EXT_BIAS
SCL
L
O
A
D
L1
L2
L3
SDA
SGND
ADDR
-LO
ISOLATION BOUNDARY
3 phase AC to point of load (3 phase AIM + BCM4414xD1E5135yzz)
BCM in a VIA package
+HI
-HI
+LO
EXT_BIAS
SCL
5V
SDA
SGND
ADDR
R1
-LO
SCL
ISOLATION BOUNDARY
Host PMBus™
SDA
SGND
L
O
A
D
+
–
DC
BCM in a VIA package
+HI
-HI
+LO
EXT_BIAS
SCL
5V
SDA
SGND
ADDR
R2
-LO
ISOLATION BOUNDARY
Paralleling PMBus BCM in a VIA package – connection to Host PMBus
BCM® in a VIA Package
Page 2 of 43
Rev 1.7
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BCM4414xD1E5135yzz
Typical Applications (Cont.)
Host PMBus™
PMBus
+
–
V
EXT
SGND
SGND
SGND
PRM
BCM in a VIA Package
ENABLE
TRIM
VAUX
enable/disable
switch
EXT_BIAS
SCL
REF/
REF_EN
VTM
V
OUT
Adaptive Loop Temperature Feedback
VTM Start Up Pulse
AL
VT
VC
IFB
3
SHARE/
CONTROL NODE
SDA
PRM_SGND
}
R
R
AL_PRM
TRIM_PRM
PRM_SGND
SGND
R
SGND
LOAD
C
R
O_VTM_CER
ADDR
I_PRM_DAMP
O_PRM_DAMP
FUSE
+HI
+IN
–IN
+OUT
–OUT
+LO
–LO
L
L
I_PRM_FLT
O_PRM_FLT
C
V
C
R
I_PRM_CER
HI
HI
O_PRM_CER
–HI
SGND
HV
LV
ISOLATION BOUNDARY
HV
LV
ISOLATION BOUNDARY
SOURCE_RTN
LOAD_RTN
PRM_SGND
BCM4414xD1E5135yzz + PRM + VTM, Adaptive Loop Configuration – connection to Host PMBus
Host PMBus™
PMBus
+
–
V
EXT
SGND
SGND
SGND
V
REF
BCM in a VIA Package
PRM_SGND
REF 3312
IN OUT
PRM
PRM_SGND
Voltage Sense and Error Amplifier
(Differential)
EXT_BIAS
SCL
GND
VAUX
ENABLE
TRIM
enable/disable
switch
VTM
REF/
REF_EN
PRM_SGND
PRM_SGND
3
VT
VC
IFB
TM
VC
+OUT
AL
Voltage Reference with Soft Start
SDA
SHARE/
}
VTM Start up Pulse
CONTROL NODE
SGND
ADDR
SGND
PRM_SGND
V
+
V –
PC
VOUT
+IN
R
R
LOAD
SGND
C
–IN
I_PRM_DAMP
O_PRM_DAMP
O_VTM_CER
FUSE
+HI
+LO
–LO
+IN
–IN
+OUT
–OUT
+IN
L
External Current Sense L
O_PRM_FLT
C
C
V
I_PRM_FLT
C
O_PRM_CER
HI
HI
I_PRM_ELEC
–HI
–IN
–OUT
SGND
HV
LV
HV
LV
ISOLATION BOUNDARY
SOURCE_RTN
ISOLATION BOUNDARY
PRM_SGND
0 Ω
BCM4414xD1E5135yzz + PRM + VTM, Remote Sense Configuration – connection to Host PMBus
BCM® in a VIA Package
Page 3 of 43
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BCM4414xD1E5135yzz
Pin Configuration
1
TOP VIEW
3
+HI
–HI
+LO
5
6
7
8
9
EXT BIAS
SCL
PMBus™
SDA
SGND
ADDR
–LO
2
4
BCM in a 4414 VIA Package - Chassis (Lug) Mount
2
TOP VIEW
4
–HI
+HI
–LO
9
8
7
6
5
ADDR
SGND
SDA
PMBus™
SCL
EXT BIAS
+LO
1
3
BCM in a 4414 VIA Package - Board (PCB) Mount
Note: The dot on the VIA housing indicates the location of the signal pin 9.
Pin Descriptions
Pin Number
Signal Name
Type
Function
High voltage side positive power terminal
1
2
+HI
–HI
HIGH SIDE POWER
HIGH SIDE POWER
RETURN
High voltage side negative power terminal
Low voltage side positive power terminal
Low voltage side negative power terminal
LOW SIDE
POWER
3
4
+LO
–LO
LOW SIDE
POWER RETURN
5
6
7
EXT BIAS
SCL
INPUT
INPUT
5V supply input
I2C™ Clock, PMBus™ Compatible
I2C Data, PMBus™ Compatible
SDA
INPUT/OUTPUT
LOW SIDE
SIGNAL RETURN
8
9
SGND
ADDR
Signal Ground
INPUT
Address assignment - Resistor based
Notes: All signal pins (5, 6, 7, 8, 9) are referenced to the low voltage side and isolated from the high voltage side.
Keep SGND signal separated from the low voltage side power return terminal (–LO) in electrical design.
BCM® in a VIA Package
Page 4 of 43
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BCM4414xD1E5135yzz
Absolute Maximum Ratings
The absolute maximum ratings below are stress ratings only. Operation at or beyond these maximum ratings can cause permanent damage to the device.
Parameter
Comments
Min
Max
480
N/A
60
Unit
V
+HI to –HI
–1
HI_DC or LO_DC Slew Rate
+LO to –LO
Internal hot-swap circuitry
V/µs
V
–1
–0.3
10
V
EXT BIAS to SGND
0.15
5.5
5.5
3.6
A
SCL to SGND
SDA to SGND
ADDR to SGND
–0.3
–0.3
–0.3
2121
2121
707
V
V
V
Basic insulation (high voltage side to case)
VDC
VDC
VDC
Isolation Voltage /
Dielectric Withstand
Basic insulation (high voltage side to low voltage side) [b]
Functional insulation (low voltage side to case)
[b] The absolute maximum rating listed above for dielectric withstand (high voltage side to low voltage side) refers to the VIA package. The internal safety
approved isolating component (ChiP) provides reinforced insulation (4242V) from high voltage side to low voltage side. However, the VIA package itself can
only be tested at a basic insulation value (2121V).
BCM® in a VIA Package
Page 5 of 43
Rev 1.7
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BCM4414xD1E5135yzz
Electrical Specifications
Specifications apply over all line and load conditions, unless otherwise noted; boldface specifications apply over the temperature range of
–40°C ≤ TCASE ≤ 100°C (T-Grade); all other specifications are at TCASE = 25ºC unless otherwise noted.
Attribute
Symbol
Conditions / Notes
Min
Typ
Max
Unit
General Powertrain Specification – Forward Direction Operation (High Voltage Side to Low Voltage Side)
HI Side Voltage Range
(Continuous)
VHI_DC
260
260
410
410
130
V
V
V
HI Side Voltage Range
(Transient)
VHI_TRANS
VµC_ACTIVE
HI Side Voltage
Initialization Threshold
HI side voltage where internal controller is initialized,
(powertrain inactive)
Disabled, VHI_DC = 400V
TCASE ≤ 100ºC
2
HI Side Quiescent Current
No Load Power Dissipation
IHI_Q
mA
4
VHI_DC = 400V, TCASE = 25ºC
VHI_DC = 400V
10.5
17
21
18
22
6
PHI_NL
W
VHI_DC = 260 – 410V, TCASE = 25 ºC
VHI_DC = 260 – 410V
VHI_DC = 410V, CLO_EXT = 100µF,
RLOAD_LO = 25% of full load current
6
HI Side Inrush Current Peak
IHI_INR_PK
A
TCASE ≤ 100ºC
12
DC HI Side Current
IHI_IN_DC
K
ILO_OUT_DC
ILO_OUT_PULSE
At ILO_OUT_DC = 35A, TCASE ≤ 70ºC
4.5
A
V/V
A
High voltage to low voltage K = VLO_DC / VHI_DC
at no load
,
Transformation Ratio
1/8
LO Side Current (Continuous)
LO Side Current (Pulsed)
TCASE ≤ 70ºC
35
40
2ms pulse, 25% duty cycle, ILO_OUT_AVG ≤ 50% rated
ILO_OUT_DC
A
VHI_DC = 400V, ILO_OUT_DC = 35A
96.5
95.3
96.8
95.7
94.5
18
97.2
Efficiency (Ambient)
ηAMB
VHI_DC = 260 – 410V, ILO_OUT_DC = 35A
VHI_DC = 400V, ILO_OUT_DC = 17.5A
%
97.6
96.5
Efficiency (Hot)
ηHOT
η20%
VHI_DC = 400V, ILO_OUT_DC = 35A, TCASE = 70°C
7A < ILO_OUT_DC < 35A
%
%
Efficiency (Over Load Range)
RLO_COLD
RLO_AMB
RLO_HOT
FSW
VHI_DC = 400V, ILO_OUT_DC = 35A, TCASE = –40°C
VHI_DC = 400V, ILO_OUT_DC = 35A
22
25
33
LO Side Output Resistance
27
29.5
34.8
1.10
mΩ
VHI_DC = 400V, ILO_OUT_DC = 35A, TCASE = 70°C
Low side voltage ripple frequency = 2x FSW
32
37
Switching Frequency
LO Side Voltage Ripple
1.05
1.14
MHz
mV
CLO_EXT = 0µF, ILO_OUT_DC = 35A, VHI_DC = 400V,
20MHz BW
250
VLO_OUT_PP
TCASE ≤ 100ºC
550
BCM® in a VIA Package
Page 6 of 43
Rev 1.7
01/2018
BCM4414xD1E5135yzz
Electrical Specifications (Cont.)
Specifications apply over all line and load conditions, unless otherwise noted; boldface specifications apply over the temperature range of
–40°C ≤ TCASE ≤ 100°C (T-Grade); all other specifications are at TCASE = 25ºC unless otherwise noted.
Attribute
Symbol
Conditions / Notes
Min
Typ
Max
Unit
General Powertrain Specification – Forward Direction Operation (High Voltage Side to Low Voltage Side), Cont.
Effective HI Side Capacitance
(Internal)
CHI_INT
CLO_INT
Effective value at 400VHI_DC
Effective value at 50VLO_DC
0.4
µF
µF
µF
Effective LO Side Capacitance
(Internal)
37.6
Excessive capacitance may drive module into short
circuit protection
Rated LO Side Capacitance (External) CLO_OUT_EXT
100
Rated LO Side Capacitance (External),
CLO_OUT_AEXT
CLO_OUT_AEXT Max = N • 0.5 • CLO_OUT_EXT MAX, where
N = the number of units in parallel
Parallel Array Operation
Powertrain Hardware Protection Specification – Forward Direction Operation (High Voltage Side to Low Voltage Side)
• These built-in powertrain protections are fixed in hardware and cannot be configured through PMBus™.
• When duplicated in supervisory limits, hardware protections serve a secondary role and become active when supervisory limits are
disabled through PMBus.
Start up into a persistent fault condition. Non-latching
fault detection given VHI_DC > VHI_UVLO+
Auto Restart Time
tAUTO_RESTART
VHI_OVLO+
VHI_OVLO–
290
430
420
360
450
440
ms
V
HI Side Overvoltage
Lockout Threshold
440
430
10
HI Side Overvoltage
Recovery Threshold
V
HI Side Overvoltage
Lockout Hysteresis
VHI_OVLO_HYST
tHI_OVLO
V
HI Side Overvoltage
Lockout Response Time
10
µs
ms
A
From powertrain active. Fast current limit protection
disabled during soft start
HI Side Soft-Start Time
tHI_SOFT-START
ILO_OUT_OCP
tLO_OUT_OCP
ILO_OUT_SCP
tLO_OUT_SCP
tOTP+
1
LO Side Overcurrent Trip Threshold
37.5
52
47
59
LO Side Overcurrent
Response Time Constant
Effective internal RC filter
3.6
ms
A
LO Side Short Circuit
Protection Trip Threshold
LO Side Short Circuit
Protection Response Time
1
µs
°C
Overtemperature
Shutdown Threshold
Internal
125
BCM® in a VIA Package
Page 7 of 43
Rev 1.7
01/2018
BCM4414xD1E5135yzz
Electrical Specifications (Cont.)
Specifications apply over all line and load conditions, unless otherwise noted; boldface specifications apply over the temperature range of
–40°C ≤ TCASE ≤ 100°C (T-Grade); all other specifications are at TCASE = 25ºC unless otherwise noted.
Attribute
Symbol
Conditions / Notes
Min
Typ
Max
Unit
Powertrain Supervisory Limits Specification – Forward Direction Operation (High Voltage Side to Low Voltage Side)
• These supervisory limits are set in the internal controller and can be reconfigured or disabled through PMBus™.
• When disabled, the powertrain protections presented in the previous table will intervene during fault events.
HI Side Overvoltage
Lockout Threshold
VHI_OVLO+
VHI_OVLO–
VHI_OVLO_HYST
tHI_OVLO
420
405
436
426
10
450
440
V
V
HI Side Overvoltage
Recovery Threshold
HI Side Overvoltage
Lockout Hysteresis
V
HI Side Overvoltage
Lockout Response Time
100
226
244
15
µs
V
HI Side Undervoltage
Lockout Threshold
VHI_UVLO–
200
225
250
259
HI Side Undervoltage
Recovery Threshold
VHI_UVLO+
VHI_UVLO_HYST
tHI_UVLO
V
HI Side Undervoltage
Lockout Hysteresis
V
HI Side Undervoltage
Lockout Response Time
100
µs
From VHI_DC = VHI_UVLO+ to powertrain active
HI Side Undervoltage Start-Up Delay tHI_UVLO+_DELAY (i.e., one time start-up delay from application of VHI_DC
to VLO_DC
20
ms
)
LO Side Overcurrent
Trip Threshold
ILO_OUT_OCP
tLO_OUT_OCP
tOTP+
42.5
45
2
47.5
A
LO Side Overcurrent
Response Time Constant
Effective internal RC filter
Internal
ms
°C
°C
Overtemperature
Shutdown Threshold
125
Overtemperature
Recovery Threshold
tOTP–
Internal
105
110
115
C-Grade
T-Grade
–25
–45
Undertemperature Shutdown
Threshold (Internal)
tUTP
°C
s
Start up into a persistent fault condition. Non-latching
fault detection given VHI_DC > VHI_UVLO+
Undertemperature Restart Time
tUTP_RESTART
3
BCM® in a VIA Package
Page 8 of 43
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BCM4414xD1E5135yzz
40
35
30
25
20
15
10
5
0
-60
-40
-20
0
20
40
60
80
100
120
Case Temperature (ºC)
260 – 410V
Figure 1 — Specified thermal operating area
1. The BCM in a VIA package is cooled through the bottom case (bottom housing).
2. The thermal rating is based on typical measured device efficiency.
3. The case temperature in the graph is the measured temperature of the bottom housing, such that the internal operating temperature
does not exceed 125°C.
2500
2250
2000
1750
1500
1250
1000
750
50
45
40
35
30
25
20
15
10
5
500
250
0
0
260 275 290 305 320 335 350 365 380 395 410
260 275 290 305 320 335 350 365 380 395 410
HI Side Voltage (V)
HI Side Voltage (V)
ILO_OUT_DC
ILO_OUT_PULSE
PLO_OUT_DC
PLO_OUT_PULSE
Figure 2 — Specified electrical operating area using rated RLO_HOT
110
100
90
80
70
60
50
40
30
20
10
0
0
25
50
75
100
LO Side Current (% ILO_DC
)
Figure 3 — Specified HI side start up into load current and external capacitance
BCM® in a VIA Package
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Rev 1.7
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BCM4414xD1E5135yzz
PMBus™ Reported Characteristics
Specifications apply over all line and load conditions, unless otherwise noted; boldface specifications apply over the temperature range of
–40°C ≤ TCASE ≤ 100°C (T-Grade); all other specifications are at TCASE = 25ºC unless otherwise noted.
Monitored Telemetry
• The current telemetry is only available in forward operation. The input and output current reported value is not supported in reverse operation.
ACCURACY
(RATED RANGE)
FUNCTIONAL
REPORTING RANGE
UPDATE
RATE
ATTRIBUTE
PMBus™ READ COMMAND
REPORTED UNITS
HI Side Voltage
HI Side Current
LO Side Voltage [c]
LO Side Current
LO Side Resistance
Temperature [d]
(88h) READ_VIN
(89h) READ_IIN
5%(LL – HL)
130 to 450V
–0.85 to 5.9A
16.25 to 56.25V
–6.8 to 47.5A
10 to 40mΩ
100µs
100µs
100µs
100µs
100ms
100ms
VACTUAL = VREPORTED x 10–1
IACTUAL = IREPORTED x 10–3
VACTUAL = VREPORTED x 10–1
IACTUAL = IREPORTED x 10–2
RACTUAL = RREPORTED x 10–5
TACTUAL = TREPORTED
20% (10 – 20% of FL)
5% (20 – 133% of FL)
(8Bh) READ_VOUT
5% (LL – HL)
20% (10 – 20% of FL)
5% (20 – 133% of FL)
(8Ch) READ_IOUT
5% (50 – 100% of FL) at NL
10% (50 – 100% of FL) (LL – HL)
(D4h) READ_ROUT
(8Dh) READ_TEMPERATURE_1
7°C (Full Range)
–55 to 130ºC
[c] Default READ LO Side Voltage returned when unit is disabled = –300V.
[d] Default READ Temperature returned when unit is disabled = –273°C.
Variable Parameters
• Factory setting of all Thresholds and Warning limits listed below are 100% of specified protection values.
• Variables can be written only when module is disabled with VHI < VHI_UVLO– and external bias (VDDB) applied.
• Module must remain in a disabled mode for 3ms after any changes to the variables below to allow sufficient time to commit changes to EEPROM.
FUNCTIONAL
REPORTING
RANGE
ACCURACY
(RATED RANGE)
DEFAULT
ATTRIBUTE
PMBusTM COMMAND
CONDITIONS / NOTES
VALUE
100%
100%
100%
100%
100%
100%
100%
0ms
HI Side Overvoltage
Protection Limit
VHI_OVLO– is automatically 3%
lower than this set point
(55h) VIN_OV_FAULT_LIMIT
(57h) VIN_OV_WARN_LIMIT
(D7h) DISABLE_FAULTS
(5Bh) IIN_OC_FAULT_LIMIT
(5Dh) IIN_OC_WARN_LIMIT
(4Fh) OT_FAULT_LIMIT
5% (LL – HL)
5% (LL – HL)
5% (LL – HL)
130 – 435V
130 – 435V
130 – 260V
0 – 5.625A
0 – 5.625A
0 – 125°C
0 – 125°C
0 – 100ms
HI Side Overvoltage
Warning Limit
HI Side Undervoltage
Protection Limit
Can only be disabled to a preset
default value
HI Side Overcurrent
Protection Limit
20% (10 – 20% of FL)
5% (20 – 133% of FL)
HI Side Overcurrent
Warning Limit
20% (10 – 20% of FL)
5% (20 – 133% of FL)
Overtemperature
Protection Limit
Internal temperature
Internal temperature
7°C (Full Range)
7°C (Full Range)
50µs
Overtemperature
Warning Limit
(51h) OT_WARN_LIMIT
(60h) TON_DELAY
Additional time delay to the
undervoltage start-up delay
Turn-On Delay
BCM® in a VIA Package
Page 10 of 43
Rev 1.7
01/2018
BCM4414xD1E5135yzz
Signal Characteristics
Specifications apply over all line and load conditions, unless otherwise noted; boldface specifications apply over the temperature range of
–40°C ≤ TCASE ≤ 100°C (T-Grade); all other specifications are at TCASE = 25ºC unless otherwise noted. Please note: For chassis mount model, Vicor part
number 42550 will be needed for applications requiring the use of the signal pins. Signal cable 42550 is rated up to five insertions and extractions.
To avoid unnecessary stress on the connector, the cable should be appropriately strain relieved.
EXT. BIAS (VDDB) Pin
• VDDB powers the internal controller.
• VDDB needs to be applied to enable and disable the BCM through PMBus™ control (using OPERATION COMMAND), and to adjust warning and
protection thresholds.
• VDDB voltage not required for telemetry; however, if VDDB is not applied, telemetry information will be lost when VIN is removed.
SIGNAL TYPE
STATE
ATTRIBUTE
VDDB Voltage
SYMBOL
VVDDB
CONDITIONS / NOTES
MIN
TYP
MAX UNIT
4.5
5
9
V
mA
A
Regular
Operation
VDDB Current Consumption
Inrush Current Peak
Turn On Time
IVDDB
50
INPUT
IVDDB_INR
tVDDB_ON
VVDDB slew rate = 1V/µs
From VVDDB_MIN to PMBus active
3.5
1.5
Start Up
ms
SGND Pin
• All PMBus interface signals (SCL, SDA, ADDR) are referenced to SGND pin.
• SGND pin also serves as return pin (ground pin) for VDDB.
• Keep SGND signal separated from the low voltage side power return terminal (–LO) in electrical design.
Address (ADDR) Pin
• This pin programs the address using a resistor between ADDR pin and signal ground.
• The address is sampled during start up and is stored until power is reset. This pin programs only a Fixed and Persistent address.
• This pin has an internal 10kΩ pullup resistor to 3.3V.
• 16 addresses are available. The range of each address is 206.25mV (total range for all 16 addresses is 0 – 3.3V).
SIGNAL TYPE
STATE
ATTRIBUTE
ADDR Input Voltage
ADDR Leakage Current
ADDR Registration Time
SYMBOL
VSADDR
ISADDR
CONDITIONS / NOTES
See address section
MIN
TYP
MAX UNIT
0
3.3
1
V
Regular
Operation
MULTI‐LEVEL
INPUT
Leakage current
From VVDDB_MIN
µA
ms
Start Up
tSADDR
1
BCM® in a VIA Package
Page 11 of 43
Rev 1.7
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BCM4414xD1E5135yzz
Serial Clock input (SCL) AND Serial Data (SDA) Pins
• High power SMBus specification and SMBus physical layer compatible. Note that optional SMBALERT# is not supported.
• PMBusTM command compatible.
SIGNAL TYPE
STATE
ATTRIBUTE
SYMBOL
CONDITIONS / NOTES
MIN
TYP
MAX UNIT
Electrical Parameters
VIH
VIL
2.1
3
V
Input Voltage Threshold
Output Voltage Threshold
0.8
V
V
VOH
VOL
0.4
10
V
Leakage Current
ILEAK_PIN
ILOAD
Unpowered device
µA
mA
Signal Sink Current
VOL = 0.4V
4
Total capacitive load of
one device pin
Signal Capacitive Load
CI
10
pF
Signal Noise Immunity
Timing Parameters
Operating Frequency
VNOISE_PP
10 – 100MHz
300
mV
FSMB
tBUF
tHD:STA
tSU:STA
Idle state = 0Hz
10
400
kHz
µs
Free Time Between
Stop and Start Condition
1.3
DIGITAL
Regular
Hold Time After Start or
Repeated Start Condition
First clock is generated
after this hold time
INPUT/OUTPUT
Operation
0.6
0.6
µs
µs
Repeat Start Condition
Set-Up Time
Stop Condition Set-Up Time
Data Hold Time
tSU:STO
tHD:DAT
tSU:DAT
tTIMEOUT
tLOW
0.6
300
100
25
µs
ns
ns
ms
µs
µs
Data Set-Up Time
Clock Low Time Out
Clock Low Period
35
1.3
0.6
Clock High Period
tHIGH
50
25
Cumulative Clock Low
Extend Time
tLOW:SEXT
ms
ns
ns
Clock or Data Fall Time
Clock or Data Rise Time
tF
20
20
300
300
tR
tLOW tR
tF
SCL
VIH
VIL
tHIGH
tSU,DAT
tHD,STA
tHD,DAT
tSU,STA
tSU,STO
SDA
VIH
VIL
tBUF
P
S
S
P
BCM® in a VIA Package
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Timing Diagram (Forward Direction)
BCM® in a VIA Package
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Application Characteristics
Temperature controlled via top side cold plate, unless otherwise noted. All data presented in this section are collected from units processing power in the
forward direction (high voltage side to low voltage side). See associated figures for general trend data.
20
18
16
14
12
10
8
98.0
97.5
97.0
96.5
96.0
95.5
95.0
94.5
94.0
6
4
2
0
-40
-20
0
20
40
60
80
100
260 275 290 305 320 335 350 365 380 395 410
Case Temperature (ºC)
HI Side Voltage (V)
VHI_DC
:
TCASE
:
260V
400V
410V
-40°C
25°C
70°C
Figure 4 — No load power dissipation vs. VHI_DC
Figure 5 — Full load efficiency vs. temperature
99
97
95
93
91
89
87
85
83
81
79
80
72
64
56
48
40
32
24
16
8
0
0.0 3.5 7.0 10.5 14.0 17.5 21.0 24.5 28.0 31.5 35.0
0.0 3.5 7.0 10.5 14.0 17.5 21.0 24.5 28.0 31.5 35.0
LO Side Current (A)
LO Side Current (A)
VHI_DC
:
260V
400V
410V
VHI_DC
:
260V
400V
410V
Figure 6 — Efficiency at TCASE = –40°C
Figure 7 — Power dissipation at TCASE = –40°C
99
97
95
93
91
89
87
85
83
81
79
80
72
64
56
48
40
32
24
16
8
0
0.0 3.5 7.0 10.5 14.0 17.5 21.0 24.5 28.0 31.5 35.0
0.0 3.5 7.0 10.5 14.0 17.5 21.0 24.5 28.0 31.5 35.0
LO Side Current (A)
LO Side Current (A)
VHI_DC
:
260V
400V
410V
VHI_DC
:
260V
400V
410V
Figure 8 — Efficiency at TCASE = 25°C
Figure 9 — Power dissipation at TCASE = 25°C
BCM® in a VIA Package
Page 14 of 43
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99
97
95
93
91
89
87
85
83
81
79
80
72
64
56
48
40
32
24
16
8
0
0.0 3.5 7.0 10.5 14.0 17.5 21.0 24.5 28.0 31.5 35.0
0.0 3.5 7.0 10.5 14.0 17.5 21.0 24.5 28.0 31.5 35.0
LO Side Current (A)
LO Side Current (A)
VHI_DC
:
260V
400V
410V
VHI_DC
:
260V
400V
410V
Figure 10 — Efficiency at TCASE = 70°C
Figure 11 — Power dissipation at TCASE = 70°C
50
45
40
35
30
25
20
15
10
5
300
270
240
210
180
150
120
90
60
30
0
0
-40
-20
0
20
40
60
80
100
0.0 3.5 7.0 10.5 14.0 17.5 21.0 24.5 28.0 31.5 35.0
LO Side Current (A)
Case Temperature (ºC)
VHI_DC
:
400V
ILO_DC
:
35A
Figure 12 — RLO vs. temperature; Nominal VHI_DC
Figure 13 — VLO_OUT_PP vs. ILO_DC ; No external CLO_OUT_EXT Board
.
ILO_DC = 35A at TCASE = 70°C
mounted module, scope setting: 20MHz analog BW
BCM® in a VIA Package
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Figure 14 — Full load LO side voltage ripple, 10µF CHI_IN_EXT
;
Figure 15 — 0 – 35A transient response:
no external CLO_OUT_EXT Board mounted module,
CHI_IN_EXT = 10µF, no external CLO_OUT_EXT
.
scope setting: 20MHz analog BW
Figure 16 — 35– 0A transient response:
Figure 17 — Start up from application of VHI_DC = 400V, 25% ILO_DC,
CHI_IN_EXT = 10µF, no external CLO_OUT_EXT
100% CLO_OUT_EXT
Figure 18 — Start up from application of OPERATION COMMAND
with pre-applied VHI_DC = 400V, 25% ILO_DC
,
100% CLO_OUT_EXT
BCM® in a VIA Package
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General Characteristics
Specifications apply over all line and load conditions, unless otherwise noted; boldface specifications apply over the temperature range of
–40°C ≤ TCASE ≤ 100°C (T-Grade); all other specifications are at TCASE = 25ºC unless otherwise noted.
Attribute
Symbol
Conditions / Notes
Min
Typ
Max
Unit
Mechanical
Length
L
L
Lug (Chassis) Mount
110.30 [4.34] 110.55 [4.35] 110.80 [4.36]
112.51 [4.43] 112.76 [4.44] 113.01 [4.45]
mm [in]
mm [in]
mm [in]
mm [in]
cm3 [in3]
g [oz]
Length
PCB (Board) Mount
Width
W
H
35.29 [1.39]
35.54 [1.40]
9.40 [0.37]
36.93 [2.25]
140.5 [4.96]
35.79 [1.41]
Height
9.019 [0.355]
9.781 [0.385]
Volume
Weight
Vol
W
Without heatsink
Pin Material
Underplate
C145 copper
Low stress ductile Nickel
Palladium
50
0.8
100
6
µin
µin
µin
Pin Finish (Gold)
Pin Finish (Tin)
Soft Gold
0.12
200
2
Whisker resistant matte Tin
400
Thermal
BCM4414xD1E5135yzz (T-Grade)
BCM4414xD1E5135yzz (C-Grade)
–40
–20
125
125
Operating Internal Temperature
Operating Case Temperature
TINT
BCM4414xD1E5135yzz (T-Grade),
derating applied, see safe thermal
operating area
–40
–20
100
100
°C
TCASE
BCM4414xD1E5135yzz (C-Grade),
derating applied, see safe thermal
operating area
Estimated thermal resistance to
maximum temperature internal
component from isothermal top
Thermal Resistance Top Side
θINT_TOP
1.24
0.63
°C/W
°C/W
Estimated thermal resistance of thermal
coupling between the top and bottom
case surfaces
Thermal Resistance Coupling Between
Top Case and Bottom Case
θHOU
Estimated thermal resistance to
maximum temperature internal
component from isothermal bottom
Thermal Resistance Bottom Side
Thermal Capacity
θINT_BOT
1.41
54
°C/W
Ws/°C
Assembly
BCM4414xD1E5135yzz (T-Grade)
BCM4414xD1E5135yzz (C-Grade)
–40
–40
125
125
°C
°C
Storage Temperature
ESD Withstand
TST
Human Body Model,
“ESDA / JEDEC JDS-001-2012” Class I-C
(1kV to < 2kV)
ESDHBM
1000
200
Charge Device Model,
“JESD 22-C101-E” Class II (200V to
< 500V)
ESDCDM
BCM® in a VIA Package
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General Characteristics (Cont.)
Specifications apply over all line and load conditions, unless otherwise noted; boldface specifications apply over the temperature range of
–40°C ≤ TCASE ≤ 100°C (T-Grade); all other specifications are at TCASE = 25ºC unless otherwise noted.
Attribute
Symbol
Conditions / Notes
Safety
Min
Typ
Max
Unit
Isolation Capacitance
CHI_LO
RHI_LO
Unpowered unit
620
10
780
940
pF
Isolation Resistance
At 500VDC
MΩ
MIL-HDBK-217Plus Parts Count - 25°C
Ground Benign, Stationary, Indoors /
Computer
3.53
3.90
MHrs
MHrs
MTBF
Telcordia Issue 2 - Method I Case III;
25°C Ground Benign, Controlled
cTÜVus EN 60950-1
cURus UL 60950-1
Agency Approvals / Standards
CE Marked for Low Voltage Directive and RoHS Recast Directive, as applicable
BCM® in a VIA Package
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BCM in a VIA Package
IHI
ILO
RLO
+
+
V•I
K
K • ILO
K • VHI
+
–
+
–
VHI
VLO
IHI_Q
–
–
Figure 19 — BCM DC model (Forward Direction)
The BCM uses a high frequency resonant tank to move energy
from the high voltage side to the low voltage side and vice versa.
The resonant LC tank, operated at high frequency, is amplitude
modulated as a function of the HI side voltage and the LO side
current. A small amount of capacitance embedded in the high
voltage side and low voltage side stages of the module is sufficient
for full functionality and is key to achieving high power density.
The effective DC voltage transformer action provides additional
interesting attributes. Assuming that RLO = 0Ω and IHI_Q = 0A,
Equation 3 now becomes Equation 1 and is essentially load
independent, resistor R is now placed in series with VHI.
R
The BCM4414xD1E5135yzz can be simplified into the model
shown in Figure 19.
BCM
V
LO
+
–
K = 1/8
VHI
At no load:
VLO = VHI • K
(1)
K represents the “turns ratio” of the BCM.
Rearranging Eq (1):
Figure 20 — K = 1/8 BCM with series HI side resistor
The relationship between VHI and VLO becomes:
V = V – I • R • K
VLO
K =
(2)
VHI
(5)
(
)
LO
HI
HI
In the presence of a load, VLO is represented by:
Substituting the simplified version of Equation 4
(IHI_Q is assumed = 0A) into Equation 5 yields:
VLO = VHI • K – ILO • RLO
(3)
VLO = VHI • K – ILO • R • K2
(6)
and ILO is represented by:
This is similar in form to Equation 3, where RLO is used to represent
the characteristic impedance of the BCM. However, in this case a
real resistor, R, on the high voltage side of the BCM is effectively
scaled by K2 with respect to the low voltage side.
IHI – IHI_Q
(4)
ILO
=
K
RLO represents the impedance of the BCM and is a function of the
RDS_ON of the HI side and LO side MOSFETs, PC board resistance of
HI side and LO side boards and the winding resistance of the power
transformer. IHI_Q represents the HI side quiescent current of the
BCM controller, gate drive circuitry and core losses.
Assuming that R = 1Ω, the effective R as seen from the low voltage
side is 15.6mΩ, with K = 1/8.
BCM® in a VIA Package
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A similar exercise can be performed with the addition of a
capacitor or shunt impedance at the high voltage side of the
BCM. A switch in series with VHI is added to the circuit. This is
depicted in Figure 21.
Low impedance is a key requirement for powering a high-current,
low-voltage load efficiently. A switching regulation stage
should have minimal impedance while simultaneously providing
appropriate filtering for any switched current. The use of a BCM
between the regulation stage and the point of load provides a
dual benefit of scaling down series impedance leading back to
the source and scaling up shunt capacitance or energy storage
as a function of its K factor squared. However, these benefits are
not achieved if the series impedance of the BCM is too high. The
impedance of the BCM must be low, i.e., well beyond the crossover
frequency of the system.
S
BCM
V
+
–
LO
K = 1/8
C
V
HI
A solution for keeping the impedance of the BCM low involves
switching at a high frequency. This enables the use of small
magnetic components because magnetizing currents remain low.
Small magnetics mean small path lengths for turns. Use of low loss
core material at high frequencies also reduces core losses.
Figure 21 — BCM with HI side capacitor
The two main terms of power loss in the BCM module are:
A change in VHI with the switch closed would result in a change in
capacitor current according to the following equation:
ꢀnNo load power dissipation (PHI_NL): defined as the power used to
power up the module with an enabled powertrain at no load.
ꢀnResistive loss (PRLO): refers to the power loss across the BCM
dVHI
module modeled as pure resistive impedance.
IC (t) = C
(7)
dt
PDISSIPATED = PHI_NL + PR
(10)
Assume that with the capacitor charged to VHI, the switch is
opened and the capacitor is discharged through the idealized
BCM. In this case,
LO
Therefore,
IC = ILO • K
(8)
PLO_OUT = PHI_IN – PDISSIPATED = PHI_IN – PHI_NL – PR
(11)
LO
substituting Equation 1 and 8 into Equation 7 reveals:
The above relations can be combined to calculate the overall
module efficiency:
C
dVLO
dt
ILO(t) =
•
(9)
K2
PLO_OUT
PHI_IN
PHI_IN – PHI_NL – PR
PHI_IN
LO
η =
=
(12)
The equation in terms of the LO side has yielded a K2 scaling factor
for C, specified in the denominator of the equation.
A K factor less than unity results in an effectively larger capacitance
on the low voltage side when expressed in terms of the high
voltage side. With a K = 1/8 as shown in Figure 21, C = 1µF would
2
VHI • IHI – PHI_NL – I
• RLO
( LO)
=
VHI • IHI
appear as C = 64µF when viewed from the low voltage side.
2
PHI_NL + I
• RLO
( LO)
= 1 –
( )
VHI • IHI
BCM® in a VIA Package
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Thermal Considerations
The VIA package provides effective conduction cooling from either
of the two module surfaces. Heat may be removed from the top
surface, the bottom surface or both. The extent to which these
two surfaces are cooled is a key component for determining the
maximum power that can be processed by a VIA, as can be seen
from the specified thermal operating area in Figure 1. Since the
VIA has a maximum internal temperature rating, it is necessary to
estimate this temperature based on a system-level thermal solution.
For this purpose, it is helpful to simplify the thermal solution into
a roughly equivalent circuit where power dissipation is modeled as
a current source, isothermal surface temperatures are represented
as voltage sources and the thermal resistances are represented as
resistors. Figure 22 shows the “thermal circuit” for the VIA module.
θINT
+ TC_BOT
s
PDISS
s
Figure 23 — Single-sided cooling VIA thermal model
ꢀnDouble side cooling: while this option might bring limited
advantage to the module internal components (given the
surface-to-surface coupling provided), it might be appealing
in cases where the external thermal system requires allocating
power to two different elements, such as heatsinks with
independent airflows or a combination of chassis/air cooling.
+
θINT_TOP
TC_TOP
–
θHOU
s
–
Current Sharing
TC_BOT
θINT_BOT
+
PDISS
The performance of the BCM is based on efficient transfer
of energy through a transformer without the need of closed
loop control. For this reason, the transfer characteristic can be
approximated by an ideal transformer with a positive temperature
coefficient series resistance.
s
Figure 22 — Double-sided cooling VIA thermal model
This type of characteristic is close to the impedance characteristic
of a DC power distribution system both in dynamic (AC) behavior
and for steady state (DC) operation.
In this case, the internal power dissipation is PDISS, θINT_TOP and θINT_
BOT are the thermal resistance characteristics of the VIA module and
the top and bottom surface temperatures are represented as TC_TOP
and TC_BOT. It is interesting to note that the package itself provides
a high degree of thermal coupling between the top and bottom
case surfaces (represented in the model by the resistor θHOU). This
feature enables two main options regarding thermal designs:
When multiple BCM modules of a given part number are
connected in an array, they will inherently share the load current
according to the equivalent impedance divider that the system
implements from the power source to the point of load. Ensuring
equal current sharing among modules requires that BCM array
impedances be matched.
ꢀnSingle side cooling: the model of Figure 22 can be simplified by
calculating the parallel resistor network and using one simple
thermal resistance number and the internal power dissipation
curves; an example for bottom side cooling only is shown in
Figure 23.
Some general recommendations to achieve matched array
impedances include:
ꢀnDedicate common copper planes/wires within the PCB/Chassis
to deliver and return the current to the modules.
ꢀnProvide as symmetric a PCB/Wiring layout as possible
In this case, θINT can be derived as follows:
among modules
(θINT_TOP + θHOU) • θINT_BOT
θINT_TOP + θHOU + θINT_BOT
For further details see AN:016 Using BCM Bus Converters
in High Power Arrays.
θINT
=
(13)
BCM® in a VIA Package
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Dielectric Withstand
ZHI_EQ1
ZLO_EQ1
The chassis of the BCM in a VIA package is required to be
connected to Protective Earth when installed in the end application
and must satisfy the requirements of IEC 60950-1 for
Class I products.
BCM®1
R0_1
VLO
VHI
ZLO_EQ2
The BCM in a VIA package contains an internal safety approved
isolating component (ChiP) that provides Reinforced Insulation from
high voltage side to low voltage side. The isolating component is
individually tested for Reinforced Insulation from the high voltage
side to the low voltage side at 4242VDC prior to final assembly
of the VIA. The Reinforced Insulation can only be tested on the
completed VIA assembly at Basic Insulation values, as specified
in the electric strength Test Procedure noted in clause 5.2.2
of IEC 60950-1.
ZHI_EQ2
BCM®2
R0_2
+
Load
DC
ZLO_EQn
BCM®n
R0_n
ZHI_EQn
Test Procedure Note from IEC 60950-1
“For equipment incorporating both REINFORCED INSULATION and
lower grades of insulation, care is taken that the voltage applied
to the REINFORCED INSULATION does not overstress BASIC
INSULATION or SUPPLEMENTARY INSULATION.”
Figure 24 — BCM module array
Fuse Selection
Summary
In order to provide flexibility in configuring power systems, BCM in
a VIA package modules are not internally fused. Input line fusing
of BCM products is recommended at the system level to provide
thermal protection in case of catastrophic failure.
The final VIA assembly provides basic insulation from the high
voltage side to case, reinforced insulation from the high voltage
side to the low voltage side, and functional insulation from the
low voltage side to case. The case is required to be connected
to protective earth in the final installation. The protective earth
connection can be accomplished through a dedicated wiring
harness (example: ring terminal clamped by mounting screw) or
surface contact (example: pressure contact on bare conductive
chassis or PCB copper layer with no solder mask).
The fuse shall be selected by closely matching system
requirements with the following characteristics:
ꢀnCurrent rating
(usually greater than maximum current of BCM module)
ꢀnMaximum voltage rating
The construction of the VIA can be summarized by describing it
as a “Class II” component installed in a “Class I” subassembly.
The insulation from the high voltage side to low voltage
side can only be tested at basic insulation values on the fully
assembled VIA product.
(usually greater than the maximum possible input voltage)
ꢀnAmbient temperature
ꢀnNominal melting I2t
ꢀnRecommend fuse: 10A Littlefuse 505 Series or
10A Littlefuse 487 Series (HI side)
ChiP Isolation
Reverse Operation
BCM modules are capable of reverse power operation. Once the
unit is started, energy will be transferred from the low voltage
side back to the high voltage side whenever the low side voltage
exceeds VHI • K. The module will continue operation in this fashion
as long as no faults occur.
High voltage side
Low voltage side
SELV
The BCM4414xD1E5135yzz has not been qualified for continuous
operation in a reverse power condition. However, fault protections
that help to protect the module in forward operation will also
protect the module in reverse operation.
RI
Transient operation in reverse is expected in cases where there is
significant energy storage on the low voltage side and transient
voltages appear on the high voltage side.
Figure 25 — ChiP before final assembly in the VIA
BCM® in a VIA Package
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VIA BCM Isolation
EMI
Receiver
+HI
-HI
+LO
-LO
ChiP
High voltage side
Low voltage side
LISN
LISN
+HI
+LO
Single
DC
Power
Supply
Screen
Room /
Filters
SELV
VIA HI Side Circuit
VIA LO Side Circuit
VIA BCM
(DUT)
Load
–HI
–LO
RI
FI
BI
PE
Figure 27 — Typical test set up block diagram for
conducted emissions
Hot-Swap
Figure 26 — BCM in a VIA package after final assembly
Many applications use a power architecture based on a 380VDC
distribution bus. This supply level is emerging as a new standard
for efficient distribution of power through board, rack and chassis
mounted telecom and datacom systems. The interconnection
between the different modules is accomplished with a backplane
and motherboard. Power is commonly provided to the various
module slots via a 380VDC distribution bus.
Filtering
The BCM in a VIA package has built-in single stage EMI filtering
with Hot-Swap circuitry located on the high voltage side. The
integrated EMI filtering consists of a common mode choke,
differential mode capacitors, and Y2 common mode capacitors.
A typical test set-up block diagram for conducted emissions is
shown in Figure 27.
In the event of a fault, removal of the faulty module from the rack
is relatively easy, provided that the remaining power modules can
support the step increase in load. Plugging in the replacement
module has more potential for problems, as it presents an
uncharged capacitor load and will draw a large inrush current. This
could cause a momentary, but unacceptable interruption or sag
in the backplane power bus if not limited. Additional problems
may arise if ordinary power module connectors are used, since
the connector pins will engage and disengage in a random and
unpredictable sequence during insertion and removal.
The built-in EMI filtering reduces the HI side voltage ripple. External
LO side filtering can be added as needed, with ceramic capacitance
used as a LO side bypass for this purpose. The filtering, along
with Hot-Swap circuitry, protects the BCM in a VIA package from
overvoltage transients imposed by a system that would exceed
maximum ratings. VIA HI side and LO side voltage ranges shall not
be exceeded. An internal overvoltage function prevents operation
outside of the normal operating HI side range. However, the
VIA is exposed to the applied voltage even when disabled and
must withstand it.
Hot-Swap or hot-plug is a highly desirable feature in many
applications, but also results in several issues that must be
addressed in the system design. A number of related phenomena
occur with a live insertion and removal event, including contact
bouncing, arcing between HI side connector pins, and large voltage
and current transients. Hot-Swap circuitry in the converter modules
protects the module itself and the rest of the system from the
problems associated with live insertion.
The source response is generally the limiting factor in the
overall system response, given the wide bandwidth of the BCM.
Anomalies in the response of the source will appear at the LO side
of the module multiplied by its K factor.
Total load capacitance at the LO side of the BCM shall not exceed
the specified maximum to ensure correct operation in start up.
Due to the wide bandwidth and small LO side impedance of the
BCM, low frequency bypass capacitance and significant energy
storage may be more densely and efficiently provided by adding
capacitance at the HI side of the BCM.
This module provides a high level of integration for DC-DC
converters in 380VDC distribution systems, saving design time
and board space. To allow for maintenance, reconfiguration,
redundancy and system upgrades, the BCM in a VIA package is
designed to address the function of Hot-Swapping at the 380VDC
distribution bus. Hot-Swap circuitry, as shown in Figure 28, uses
an active MOSFET switching device in series with the HI side line.
During module insertion, the MOSFET is driven into a resistive state
to limit the inrush current as the input capacitance of the inserted
unit is charged. The MOSFET is fully enhanced once the module’s
HI side capacitor has sufficiently charged to minimize losses
during normal operation. Verification of the Hot-Swap circuitry
performance is illustrated through plots of the module’s response
to a live insertion event in Figures 30 and 31.
At frequencies less than 500kHz, the BCM appears as an
impedance of RLO between the source and load. Within this
frequency range, capacitance connected at the HI side appears as
an effective scaled capacitance on the LO side per the relationship
defined in Equation 14.
This enables a reduction in the size and number of capacitors used
in a typical system.
CHI
CLO
=
(14)
2
K
BCM® in a VIA Package
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Hot-Swap Test – Scope Pictures
V
of ChiP
HI BCM
I
of VIA
HI BCM
VHI of VIA
BCM
VLO of VIA
BCM
ChiP BCM
Charge
Pump
Hot-swap
Controller
Figure 28 — High level diagram for 384VDC BCM in a VIA package
showing internal Hot-Swap circuitry and ChiP BCM
Figure 30 — Hot-Swap start up
The BCM in a VIA package provides the opportunity to incorporate
Hot-Swap capabilities into redundant power module arrays.
This allows telecoms and other mission critical applications to
continue operating without interruption even through failure and
replacement of one or more power modules.
Ch1: IHI of BCM#2
Ch2: VLO of BCM#2
Ch3: VHI of BCM#2 shows the fast voltage transient at the high side
terminal of BCM#2
Ch4: VHI of internal ChiP BCM#2 shows the soft start charging the
high side capacitor.
Hot-Swap Test – Test circuit and Procedure
ꢀnTwo parallel BCMs in a VIA package with mercury relay#1 open
ꢀnClose mercury relay#1 and measure inrush current going into
BCM#2
+HI
–HI
+LO
–LO
+LO
–LO
Electronic
Load
Max Load
4000µF
BCM
#1
DC
Maximum Input
Voltage
Mercury
Relay #1
+HI
–HI
BCM
#2
Figure 31 — Expanded time scale version of Figure 30 showing
start up of BCM#2
Figure 29 — Hot-Swap test circuit
BCM® in a VIA Package
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System Diagram for PMBus™ Interface
5 V
EXT_BIAS
SCL
SDA
SCL
BCM in a VIA
Package
Host
PMBus™
SDA
SGND
ADDR
SGND
The controller of the BCM in a VIA package is referenced to the low voltage side signal ground (SGND).
The BCM in a VIA package provides the Host PMBus system with accurate telemetry monitoring and reporting, threshold and warning limits adjust-
ment, in addition to corresponding status flags. The standalone BCM is periodically polled for status by the host PMBus. Direct communication to the
BCM is enabled by a page command. For example, the page (0x00) prior to a telemetry inquiry points to the controller data and page (0x01) prior to a
telemetry inquiry points to the BCM parameters.
The BCM enables the PMBus compatible host interface with an operating bus speed of up to 400kHz. The BCM follows the PMBus command
structure and specification.
BCM® in a VIA Package
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Where:
PMBus™ Interface
Refer to “PMBus Power System Management Protocol Specification
Revision 1.2, Part I and II” for complete PMBus specifications details
at http://pmbus.org.
X, is a “real world” value in units (A, V, °C, s)
Y, is a two’s complement integer received from the BCM controller
m, b and R are two’s complement integers defined as follows:
Device Address
Command
TON_DELAY
Code
60h
88h
89h
8Bh
8Ch
8Dh
96h
A0h
A1h
A4h
A5h
A6h
A7h
D1h
D4h
m
R
3
1
3
1
2
0
0
0
0
0
0
0
0
0
5
b
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
The PMBus address (ADDR Pin) should be set to one of the
predetermined 16 possible addresses shown in the table below
using a resistor between the ADDR pin and SGND pin.
READ_VIN
1
READ_IIN
1
The BCM accepts only a fixed and persistent address and does not
support SMBus address resolution protocol. At initial power up, the
BCM controller will sample the address pin voltage and will keep
this address until device power is removed.
READ_VOUT [e]
READ_IOUT
1
1
READ_TEMPERATURE_1 [f]
READ_POUT
1
Slave
Address
Recommended
Resistor RADDR (Ω)
ID
HEX
1
MFR_VIN_MIN
MFR_VIN_MAX
MFR_VOUT_MIN
MFR_VOUT_MAX
MFR_IOUT_MAX
MFR_POUT_MAX
READ_K_FACTOR
READ_BCM_ROUT
1
1
2
1010 000b
1010 001b
1010 010b
1010 011b
1010 100b
1010 101b
1010 110b
1010 111b
1011 000b
1011 001b
1011 010b
1011 011b
1011 100b
1011 101b
1011 110b
1011 111b
50h
51h
52h
53h
54h
55h
56h
57h
58h
59h
5Ah
5Bh
5Ch
5Dh
5Eh
5Fh
487
1050
1
1
3
1870
1
4
2800
1
5
3920
1
65536
1
6
5230
7
6810
8
8870
[e] Default READ LO side voltage returned when BCM unit is disabled = –300V.
[f] Default READ Temperature returned when BCM unit is disabled = –273°C.
9
11300
14700
19100
25500
35700
53600
97600
316000
10
11
12
13
14
15
16
No special formatting is required when lowering the supervisory
limits and warnings.
Reported DATA Formats
The BCM controller employs a direct data format where all
reported measurements are in Volts, Amperes, Degrees Celsius,
or Seconds. The host uses the following PMBus specification
to interpret received values metric prefixes. Note that the
COEFFICIENTS command is not supported:
1
m
X =
(
• (Y • 10-R - b)
)
BCM® in a VIA Package
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Supported Command List
Command
Code
Function
Default Data Content
Data Bytes
PAGE
00h
01h
Access BCM stored information
Turn BCM on or off
00h
80h
N/A
20h
64h
64h
64h
64h
64h
64h
00h
00h
00h
00h
00h
1
1
OPERATION
CLEAR_FAULTS
CAPABILITY
03h
Clear all faults
Controller PMBusTM key capabilities set by factory
None
1
19h
OT_FAULT_LIMIT
OT_WARN_LIMIT
VIN_OV_FAULT_LIMIT
VIN_OV_WARN_LIMIT
IIN_OC_FAULT_LIMIT
IIN_OC_WARN_LIMIT
TON_DELAY
4Fh [g]
51h [g]
55h [g]
57h [g]
5Bh [g]
5Dh [g]
60h [g]
78h
Overtemperature protection
2
Overtemperature warning
2
High voltage side overvoltage protection
High voltage side overvoltage warning
High voltage side overcurrent protection
High voltage side overcurrent warning
Start-up delay in addition to fixed delay
Summary of faults
2
2
2
2
2
STATUS_BYTE
1
STATUS_WORD
STATUS_IOUT
79h
Summary of fault conditions
2
7Bh
Overcurrent fault status
1
STATUS_INPUT
7Ch
Overvoltage and undervoltage fault status
1
Overtemperature and undertemperature
fault status
STATUS_TEMPERATURE
7Dh
00h
1
STATUS_CML
7Eh
80h
88h
89h
8Bh
8Ch
8Dh
96h
98h
99h
9Ah
9Bh
9Ch
9Dh
9Eh
PMBus communication fault
Other BCM status indicator
00h
00h
1
1
STATUS_MFR_SPECIFIC
READ_VIN
Reads HI side voltage
FFFFh
2
READ_IIN
Reads HI side current
FFFFh
2
READ_VOUT
Reads LO side voltage
FFFFh
2
READ_IOUT
Reads LO side current
FFFFh
2
READ_TEMPERATURE_1
READ_POUT
Reads internal temperature
FFFFh
2
Reads LO side power
FFFFh
2
PMBUS_REVISION
MFR_ID
PMBus compatible revision
22h
1
BCM controller ID
“VI”
2
MFR_MODEL
Internal controller or BCM model
Internal controller or BCM revision
Internal controller or BCM factory location
Internal controller or BCM manufacturing date
Internal controller or BCM serial number
Minimum rated high side voltage
Maximum rated high side voltage
Minimum rated low side voltage
Maximum rated low side voltage
Maximum rated low side current
Maximum rated low side power
Reads K factor
Part Number
FW and HW revision
“AP”
18
18
2
MFR_REVISION
MFR_LOCATION
MFR_DATE
“YYWW”
Serial Number
Varies per BCM
Varies per BCM
Varies per BCM
Varies per BCM
Varies per BCM
Varies per BCM
Varies per BCM
Varies per BCM
646464646464h
4
MFR_SERIAL
16
2
MFR_VIN_MIN
MFR_VIN_MAX
MFR_VOUT_MIN
MFR_VOUT_MAX
MFR_IOUT_MAX
MFR_POUT_MAX
READ_K_FACTOR
READ_BCM_ROUT
SET_ALL_THRESHOLDS
A0h
A1h
A4h
A5h
A6h
A7h
D1h
D4h
D5h [g]
2
2
2
2
2
2
Reads low voltage side output resistance
Set supervisory warning and protection thresholds
2
6
Disable overvoltage, overcurrent or
undervoltage supervisory faults
DISABLE_FAULT
D7h [g]
00h
2
[g] The BCM must be in a disabled state with VHI < VHI_UVLO– and VDDB applied during a write message.
BCM® in a VIA Package
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Command Structure Overview
Write Byte protocol:
The Host always initiates PMBus™ communication with a START bit. All messages are terminated by the Host with a STOP bit. In a write
message, the master sends the slave device address followed by a write bit. Once the slave acknowledges, the master proceeds with the
command code and then similarly the data byte.
1
7
1
1
8
1
8
1
1
S
Slave Address Wr
A
Command Code
A
x = 0
Data Byte
A
x = 0
P
x = 0 x = 0
S
Start Condition
Repeated start Condition
Sr
Rd Read
Wr Write
X
A
P
Indicated that field is required to have the value of x
Acknowledge (bit may be 0 for an ACK or 1 for a NACK)
Stop Condition
From Master to Slave
From Slave to Master
…
Continued next line
Figure 1 — PAGE COMMAND (00h), WRITE BYTE PROTOCOL
Read Byte protocol:
A Read message begins by first sending a Write Command, followed by a REPEATED START Bit and a slave Address. After receiving the
READ bit, the BCM controller begins transmission of the Data responding to the Command. Once the Host receives the requested Data, it
terminates the message with a NACK preceding a stop condition signifying the end of a read transfer.
1
7
1
1
8
1
1
7
1
1
8
1
1
S
Slave Address Wr
A
Command Code
A
x = 0
Sr Slave Address Rd
A
Data Byte
A
x = 1
P
x = 0 x = 0
x = 1 x = 0
Figure 2 — ON_OFF_CONFIG COMMAND (02h), READ BYTE PROTOCOL
BCM® in a VIA Package
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Write Word protocol:
When transmitting a word, the lowest order byte leads the highest order byte. Furthermore, when transmitting a Byte, the least significant
bit (LSB) is sent last. Refer to System Management Bus (SMBus) specification version 2.0 for more details.
Note: Extended command and Packet Error Checking Protocols are not supported.
1
7
1
1
8
1
8
1
8
1
1
S
Slave Address Wr
A
Command Code
A
x = 0
Data Byte Low
A
x = 0
Data Byte High
A
x = 0
P
x = 0 x = 0
Figure 3 — TON_DELAY COMMAND (D6h)_WRITE WORD PROTOCOL
Read Word protocol:
1
7
1
1
8
1
1
7
1
1
8
1
8
1
1
S
Slave Address Wr
A
Command Code
A
x = 0
Sr Slave Address Rd
A
Data Byte Low
A
x = 0
Data Byte High
A
x = 1
P
x = 0 x = 0
x = 1 x = 0
Figure 4 — MFR_VIN_MIN COMMAND (88h)_READ WORD PROTOCOL
Write Block protocol:
1
7
1
1
8
1
8
1
8
1
S
Slave Address Wr
A
Command Code
A
x = 0
Byte Count = N
A
x = 0
Data Byte 1
A
x = 0
...
x = 0 x = 0
...
8
1
8
1
1
Data Byte 2
A
x = 0
...
...
Data Byte N
A
x = 0
P
Figure 5 — SET_ALL_THRESHOLDS COMMAND (D5h)_WRITE BLOCK PROTOCOL
BCM® in a VIA Package
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Read Block protocol:
1
7
1
1
8
1
1
7
1
1
8
1
S
Slave Address Wr
A
Command Code
A
x = 0
Sr Slave Address Rd
A
Data Byte = N
A
x = 0
...
x = 0 x = 0
x = 1 x = 0
...
8
1
8
1
8
1
1
Data Byte 1
A
x = 0
Data Byte 2
A
x = 0
...
...
Data Byte N
A
x = 1
P
Figure 6 — SET_ALL_THRESHOLDS COMMAND (D5h)_READ BLOCK PROTOCOL
Write Group Command protocol:
Note that only one command per device is allowed in a group command.
1
7
1
1
8
1
8
1
8
1
S
Slave Address Wr
A
Command Code
A
x = 0
Data Byte Low
A
x = 0
Data Byte High
One or more Data Bytes
A
x = 0
...
First Device
x = 0 x = 0
First Command
1
7
1
1
8
1
8
1
8
1
Sr Slave Address Wr
A
Command Code
A
Data Byte Low
A
x = 0
Data Byte High
A
...
P
Second Device
x = 0 x = 0
Second Command
x = 0
One or more Data Bytes
x = 0
1
7
1
1
8
1
8
1
8
1
Sr Slave Address Wr
A
Command Code
A
x = 0
Data Byte Low
A
x = 0
Data Byte High
One or more Data Bytes
A
x = 0
Nth Device
x = 0 x = 0
Nth Command
Figure 7 — DISABLE_FAULT COMMAND (D7h)_WRITE
BCM® in a VIA Package
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Supported Commands Transaction Type
Page Command (00h)
A direct communication to the BCM controller and a simulated
communication to non-PMBus™ devices is enabled by a page
command. Supported command access privileges with a
pre-selected PAGE are defined in the following table. Deviation
from this table generates a communication error in
STATUS_CML register.
The page command data byte of 00h prior to a command call
will address the controller specific data and a page data byte of
01h would broadcast to the BCM. The value of the Data Byte
corresponds to the pin name trailing number with the exception
of 00h and FFh.
Data Byte
Description
PAGE Data Byte
Access Type
00h
01h
BCM controller
BCM
Command
Code
00h
01h
PAGE
00h
01h
03h
19h
4Fh
R/W
R
R/W
R/W
W
OPERATION Command (01h)
OPERATION
The OPERATION command can be used to turn on and off
the connected BCM.
CLEAR_FAULTS
CAPABILITY
W
R
If synchronous start up is required in the system, it is recommended
to use the command from host PMBus in order to achieve
simultaneous array start up.
OT_FAULT_LIMIT
OT_WARN_LIMIT
VIN_OV_FAULT_LIMIT
VIN_OV_WARN_LIMIT
IIN_OC_FAULT_LIMIT
IIN_OC_WARN_LIMIT
TON_DELAY
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R
51h
55h
57h
5Bh
5Dh
60h
78h
79h
7Bh
7Ch
7Dh
7Eh
80h
88h
89h
8Bh
8Ch
8Dh
96h
98h
99h
9Ah
9Bh
9Ch
9Dh
9Eh
A0h
A1h
A4h
A5h
A6h
A7h
D1h
D4h
D5h
D7h
Unit is On when asserted (default)
Reserved
STATUS_BYTE
R/W
R
STATUS_WORD
STATUS_IOUT
R
R
R/W
R/W
R/W
STATUS_INPUT
STATUS_TEMPERATURE
STATUS_CML
R
7
6
5
4
3
2
1
0
b
1
0
0
0
0
0
0
0
R
R/W
R
STATUS_MFR_SPECIFIC
READ_VIN
R/W
R
This command accepts only two data values: 00h and 80h. If any
other value is sent the command will be rejected and a CML Data
error will result.
READ_IIN
R
R
READ_VOUT
R
READ_IOUT
R
R
R
R
R
R
R
R
R
R
R
R
R
R
R
R
R
READ_TEMPERATURE_1
READ_POUT
R
R
PMBUS_REVISION
MFR_ID
MFR_MODEL
R
R
MFR_REVISION
MFR_LOCATION
MFR_DATE
R
R
MFR_SERIAL
R
MFR_VIN_MIN
R
MFR_VIN_MAX
MFR_VOUT_MIN
MFR_VOUT_MAX
MFR_IOUT_MAX
MFR_POUT_MAX
READ_K_FACTOR
READ_BCM_ROUT
SET_ALL_THRESHOLDS
DISABLE_FAULT
R
R
R
R
R
R
R
R/W
R/W
BCM® in a VIA Package
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The VIN_UV_WARN_LIMIT (58h) and VIN_UV_FAULT_LIMIT
(59h) are set by the factory and cannot be changed by the host.
However, a host can disable the undervoltage setting using the
DISABLE_FAULT COMMAND (D7h).
CLEAR_FAULTS Command (03h)
This command clears all status bits that have been previously set.
Persistent or active faults are re-asserted again once cleared. All
faults are latched once asserted in the BCM controller. Registered
faults will not be cleared when shutting down the BCM powertrain
by recycling the BCM high side voltage or sending the
OPERATION command.
All FAULT_RESPONSE commands are unsupported. The BCM
powertrain supervisory limits and powertrain protection will behave
as described in the Electrical Specifications. In general, once a fault
is detected, the BCM powertrain will shut down and attempt to
auto-restart after a predetermined delay.
CAPABILITY Command (19h)
TON_DELAY Command (60h)
The value of this register word is set in non-volatile memory and
can only be written when the BCM is disabled.
Packet Error Checking is not supported
Maximum supported bus speed is 400kHz
The maximum possible delay is 100ms. Default value is set
to (00h). The reported value can be interpreted using the
following equation.
The Device does not have SMBALERT# pin and does
not support the SMBus Alert Response protocol
Reserved
TON_DELAYACTUAL = tREPORTED • 10-3(s)
7
6
5
4
3
2
1
0
Staggering start up in an array is possible with the TON_DELAY
Command. This delay will be in addition to any start up delay
inherent in the BCM module. For example: start up delay from
application of VHI is typically 20ms. When TON_DELAY is greater
than zero, the set delay will be added to it.
b
0
0
1
0
0
0
0
0
The BCM controller returns a default value of 20h. This value
indicates that the PMBus™ frequency supported is up to 400kHz
and that both Packet Error Checking (PEC) and SMBALERT# are
not supported.
OT_FAULT_LIMIT Command (4Fh),
OT_WARN_ LIMIT Command (51h),
VIN_OV_FAULT_ LIMIT Command (55h),
VIN_OV_WARN_ LIMIT Command (57h),
IIN_OC_FAULT_ LIMIT Command (5Bh),
IIN_OC_WARN_ LIMIT Command (5Dh)
The values of these registers are set in non-volatile memory and
can only be written when the BCM is disabled.
The values of the above mentioned faults and warnings are set by
default to 100% of the respective BCM model supervisory limits.
However, these limits can be set to a lower value. For example: In
order for a limit percentage to be set to 80%, one would send a
write command with a (50h) Data Word.
Any values outside the range of (00h – 64h) sent by a host will be
rejected, will not override the currently stored value and will set the
Unsupported Data bit in STATUS_CML.
The SET_ALL_THRESHOLDS COMMAND (D5h) combines in one
block overtemperature fault and warning limits, VHI overvoltage
fault and warning limits as well as ILO overcurrent fault and warning
limits. A delay prior to a read command of up to 200ms following a
write of new value is required.
BCM® in a VIA Package
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STATUS_BYTE (78h) and STATUS_WORD (79h)
STATUS_WORD
High Byte
Low Byte
STATUS_BYTE
Not Supported: UNKNOWN FAULT OR WARNING
Not Supported: OTHER
UNIT IS BUSY
UNIT IS OFF
Not Supported: FAN FAULT OR WARNING
Not Supported: VOUT_OV_FAULT
POWER_GOOD Negated*
IOUT_OC_FAULT
VIN_UV_FAULT
STATUS_MFR_SPECIFIC
INPUT FAULT OR WARNING
TEMPERATURE FAULT OR WARNING
IOUT/POUT FAULT OR WARNING
PMBusTM COMMUNICATION EVENT
NONE OF THE ABOVE
Not Supported: VOUT FAULT OR WARNING
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
0
1
1
1
1
0
0
0
1
1
0
1
1
1
1
0
b
* equal to POWER_GOOD#
If the BCM controller is powered through VDDB, it will retain the
last telemetry data and this information will be available to the user
via a PMBus Status request. This is in agreement with the PMBus
standard, which requires that status bits remain set until specifically
cleared. Note that in the case where the BCM VHI is lost, the status
will always indicate an undervoltage fault, in addition to any other
fault that occurred.
All fault or warning flags, if set, will remain asserted until
cleared by the host or once the BCM and VDDB power is
removed. This includes undervoltage fault, overvoltage fault,
overvoltage warning, overcurrent warning, overtemperature
fault, overtemperature warning, undertemperature fault, reverse
operation, communication faults and analog controller
shutdown fault.
NONE OF THE ABOVE bit will be asserted if either the
STATUS_MFR_SPECIFIC (80h) or the High Byte of the
STATUS WORD is set.
Asserted status bits in all status registers, with the exception of
STATUS_WORD and STATUS_BYTE, can be individually cleared.
This is done by sending a data byte with one in the bit position
corresponding to the intended warning or fault to be cleared. Refer
to the PMBus™ Power System Management Protocol Specification
– Part II – Revision 1.2 for details.
STATUS_IOUT (7Bh)
The POWER_GOOD# bit reflects the state of the device and does
not reflect the state of the POWER_GOOD# signal limits. The
POWER_GOOD_ON COMMAND (5Eh) and POWER_GOOD_OFF
COMMAND (5Fh) are not supported. The POWER_GOOD# bit is
set, when the BCM is not in the active state, to indicate that the
powertrain is inactive and not switching. The POWER_GOOD#
bit is cleared, when the BCM is in the active state, 5ms after the
powertrain is activated allowing for soft start to elapse.
POWER_ GOOD# and OFF bits cannot be cleared as they always
reflect the current state of the device.
IOUT_OC_FAULT
Not Supported: IOUT_OC_LV_FAULT
IOUT_OC_WARNING
Not Supported: IOUT_UC_FAULT
Not Supported: Current Share Fault
Not Supported: In Power Limiting Mode
Not Supported: POUT_OP_FAULT
Not Supported: POUT_OP_WARNING
The Busy bit can be cleared using CLEAR_ALL Command (03h) or
by writing either data value (40h, 80h) to PAGE (00h) using the
STATUS_BYTE (78h).
7
6
5
4
3
2
1
0
b
1
0
0
1
0
0
0
0
Fault reporting, such as SMBALERT# signal output, and host
notification by temporarily acquiring bus master status is
not supported.
Unsupported bits are indicated above. A one indicates a fault.
BCM® in a VIA Package
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The STATUS_CML data byte will be asserted when an unsupported
PMBus™ command or data or other communication fault occurs.
STATUS_INPUT (7Ch)
VIN_OV_FAULT
STATUS_MFR_SPECIFIC (80h)
VIN_OV_WARNING
Not Supported: VIN_UV_WARNING
VIN_UV_FAULT
Reserved
Reserved
Reserved
Reserved
PAGE Data Byte = (01h)
Not Supported: Unit Off For Insufficient
Input Voltage
Not Supported: IIN_OC_FAULT
Not Supported: IIN_OC_WARNING
Not Supported: PIN_OP_WARNING
Reserved
BCM UART CML
Hardware Protections Shutdown Fault
BCM Reverse Operation
7
6
5
4
3
2
1
0
b
1
1
0
1
0
0
0
0
Unsupported bits are indicated above. A one indicates a fault.
7
6
5
4
3
2
1
0
b
0
0
0
0
0
1
1
1
STATUS_TEMPERATURE (7Dh)
The reverse operation bit, if asserted, indicates that the BCM is
processing current in reverse. Reverse current reported value is
not supported.
OT_FAULT
OT_WARNING
Not Supported: UT_WARNING
The BCM has hardware protections and supervisory limits. The
hardware protections provide an additional layer of protection and
has the fastest response time. The Hardware Protections Shutdown
Fault, when asserted, indicates that at least one of the powertrain
protection faults is triggered. This fault will also be asserted if
a disabled fault event occurs after asserting any bit using the
DISABLE_FAULTS COMMAND.
UT_FAULT
Reserved
Reserved
Reserved
Reserved
The BCM UART is designed to operate with the controller UART.
If the BCM UART CML is asserted, it may indicate a hardware or
connection issue between both devices.
7
6
5
4
3
2
1
0
b
1
1
0
1
0
0
0
0
Reserved
PAGE Data Byte = (00h)
Reserved
Reserved
Unsupported bits are indicated above. A one indicates a fault.
STATUS_CML (7Eh)
BCM at PAGE (01h) is present
Reserved
Invalid Or Unsupported Command Received
Invalid Or Unsupported Data Received
Not Supported: Packet Error Check Failed
BCM UART CML
Hardware Protections Shutdown Fault
BCM Reverse Operation
Not Supported: Memory Fault Detected
Not Supported: Processor Fault Detected
Reserved
7
6
5
4
3
2
1
0
b
0
0
0
0
0
0
0
0
Other Communication Faults
Not Supported: Other Memory Or Logic
Fault
When the PAGE COMMAND (00h) data byte is equal to (00h),
the BCM Reverse operation, Analog Controller Shutdown Fault,
and BCM UART CML bit will return the result of the active BCM.
The BCM UART CML will also be asserted if the active BCM
stops responding. The BCM must communicate at least once
to the internal controller in order to trigger this FAULT.
The BCM UART CML can be cleared using the PAGE (00h)
CLEAR_FAULTS (03h) Command.
7
6
5
4
3
2
1
0
b
1
1
0
0
0
0
1
0
Unsupported bits are indicated above. A one indicates a fault.
BCM® in a VIA Package
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READ_VIN Command (88h)
READ_POUT Command (96h)
If PAGE data byte is equal to (01h), command will return the BCM’s
HI side voltage in the following format:
If PAGE data byte is equal to (01h), command will return the BCM’s
LO side power in the following format:
VHI_ACTUAL = VHI_REPORTED • 10-1(V)
PLO_ACTUAL = PLO_REPORTED (W)
If PAGE data byte is equal to (00h) command will also return the
BCM’s LO side power.
READ_IIN Command (89h)
If PAGE data byte is equal to (01h), command will return the BCM’s
HI side current in the following format:
MFR_VIN_MIN Command (A0h),
MFR_VIN_MAX Command (A1h),
MFR_VOUT_MIN Command (A4h),
MFR_VOUT_MAX Command (A5h),
MFR_IOUT_MAX Command (A6h),
MFR_POUT_MAX Command (A7h)
IHI_ACTUAL = IHI_REPORTED • 10-3(A)
If PAGE data byte is equal (00h), command will also return the
BCM’s HI side current.
These values are set by the factory and indicate the device HI
side/LO side voltage and LO side current range and LO side
power capacity.
READ_VOUT Command (8Bh)
If PAGE data byte is equal to (01h), command will return the BCM’s
LO side voltage in the following format:
If the PAGE data byte is equal to (00h – 01h), commands will report
the rated BCM HI side voltage minimum and maximum in Volts,
LO side voltage minimum and maximum in Volts, LO side current
maximum in Amperes and LO side power maximum in Watts.
VLO_ACTUAL = VLO_REPORTED • 10-1(V)
READ_IOUT Command (8Ch)
If PAGE data byte is equal to (01h), command will also return the
BCM’s LO side current in the following format:
ILO_ACTUAL = ILO_REPORTED • 10-2(A)
If PAGE data byte is equal (00h), command will return the BCM’s
LO side current.
READ_TEMPERATURE_1 Command (8Dh)
If PAGE data byte is equal to (01h), command will return the BCM’s
temperature in the following format:
TACTUAL = TREPORTED (°C)
If PAGE data byte is equal (00h), command will also return the
BCM’s temperature.
BCM® in a VIA Package
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READ_K_FACTOR Command (D1h)
DISABLE_FAULT Command (D7h)
If PAGE data byte is equal to (01h), command will return the BCM’s
K factor in the following format:
DISABLE_FAULT
MSB
LSB
K_FACTORACTUAL = K_FACTORREPORTED • 2-16(V/V)
Reserved
Reserved
Reserved
Reserved
Reserved
Reserved
IOUT_OC_FAULT
Reserved
The K factor is defined in a BCM to represent the ratio of the
transformer winding and hence is equal to VLO / VHI.
VIN_OV_FAULT
Reserved
Reserved
Reserved
Reserved
Reserved
VIN_UV_FAULT
Reserved
READ_BCM_ROUT Command (D4h)
If PAGE data byte is equal to (01h), command will return the BCM’s
LO side resistance in the following format:
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
0
1
0
0
0
0
0
0
0
0
1
0
1
0
0
0
b
BCM_RLO_ACTUAL = BCM_RLO_REPORTED • 10-5(Ω)
Unsupported bits are indicated above. A one indicates that the
supervisory fault associated with the asserted bit is disabled.
SET_ALL_THRESHOLDS Command (D5h)
The values of this register block are set in non-volatile memory and
can only be written when the BCM is disabled.
SET_ALL_THRESHOLDS_BLOCK (6 Bytes)
This command allows the host to disable the supervisory faults
and respective statuses. It does not disable the powertrain analog
protections or warnings with respect to the set limits in the
SET_ALL_THRESHOLDS Command.
IOUT_OC_WARN_ LIMIT
IOUT_OC_FAULT_ LIMIT
VIN_OV_WARN_ LIMIT
The HI side undervoltage can only be disabled to a pre-set low
limit as specified in the Monitored Telemetry Functional
Reporting Range.
VIN_OV_FAULT_ LIMIT
OT_WARN_LIMIT
OT_FAULT_LIMIT
5
4
3
2
1
0
h
64 64 64 64 64 64
The values of this register block are set in non-volatile memory and
can only be written when the BCM is disabled.
This command provides a convenient way to configure all of the
limits, or any combination of limits described previously using
one command.
VHI overvoltage, overcurrent and overtemperature values are all set
to 100% of the specified supervisory limits by default and can only
be set to a lower percentage.
To leave a particular threshold unchanged, set the corresponding
threshold data byte to a value greater than (64h).
BCM® in a VIA Package
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3. The unsupported PMBus command code response as
The BCM Controller Implementation vs.
PMBus™ Specification Rev 1.2
The BCM controller is an I2C™ compliant, SMBus™ compatible
device and PMBus command compliant device. This section denotes
some deviation, perceived as differences from the PMBus Part I and
Part II specification Rev 1.2.
described in the Fault Management and Reporting:
nꢀnDeviations from the PMBus specification:
a. PMBus section 10.2.5.3, exceptions
• The busy bit of the STATUS_BYTE as implemented can
be cleared (80h). In order to maintain compatibility with
the specification, (40h) can also be used.
1. The PMBus interface meets all Part I and II PMBus specification
requirements with the following differences to the
transport requirement.
ꢀnManufacturer Implementation of the PMBus Spec
a. PMBus section 10.5, setting the response to a detected
Unmet DC parameter Implementation vs SMBus™ spec
fault condition
PMBus
Interface
SMBus
Rev 2.0
• All powertrain responses are pre-set and cannot be
changed.
Symbol
Parameter
Units
Min Max Min Max
b. PMBus section 10.6, reporting faults and warnings
[a]
VIL
Input Low Voltage
Input High Voltage
Input Leakage per Pin
-
0.99
-
-
0.8
V
V
to the Host.
[a]
VIH
2.31
10
2.1 VVDD_IN
• SMBALERT# signal and Direct PMBus Device to Host
Communication are not supported. However, the
PMBus™ interface will set the corresponding fault status
bits and will wait for the host to poll.
[b]
ILEAK_PIN
22
-
5
µA
[a]
V
VDD_IN
= 3.3V
[b]
V
= 5V
BUS
c. PMBus section 10.7, clearing a shutdown due to a fault
2.The BCM accepts 38 PMBus command codes.
• There is no RESET pin or EN pin in the BCM.
Cycling power to the BCM will not clear a BCM
Shutdown. The BCM will clear itself once the fault
condition is removed.
Implemented commands execute functions as described in the
PMBus specification.
ꢀnDeviations from the PMBus specification:
a. Section 15, fault related commands
d. PMBus Section 10.8.1, corrupted data transmission faults:
• The Limits and Warnings unit is implemented as a
percentage (%) range from decimal (0 – 100)
of the factory set limits.
• Packet error checking is not supported.
Data Transmission Faults Implementation
This section describes data transmission faults as implemented in the BCM controller.
Response to Host
STATUS_BYTE
STATUS_CML
Section
Description
Notes
Unsupported
NAK
FFh
CML
Other Fault
Data
10.8.1
10.8.2
10.8.3
Corrupted data
No response; PEC not supported
Sending too few bits
Reading too few bits
X
X
X
X
Host sends or reads too
few bytes
10.8.4
X
X
Host sends too many
bytes
10.8.5
10.8.6
X
X
X
X
X
Reading too many bytes
X
X
X
Device will ACK own address
BUSY bit in STATUS_BYTE even if
STATUS_WORD is set
10.8.7
Device busy
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Data Content Faults Implementation
This section describes data content fault as implemented in the BCM controller.
Response
STATUS_BYTE
to Host
STATUS_CML
Section
Description
Notes
Other
Fault
Unsupported
Command
Unsupported
Data
NAK
X
CML
X
Improperly set read bit in
the address byte
10.9.1
10.9.2
10.9.3
X
Unsupported
command code
X
X
X
Invalid or
unsupported data
X
X
X
X
10.9.4
10.9.5
Data out of range
Reserved bits
No response; not a fault
BCM® in a VIA Package
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BCM in VIA Package Chassis (Lug) Mount Package Mechanical Drawing
'
(5
ꢀ
ꢋꢀ
3
4
1
2
BCM® in a VIA Package
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BCM4414xD1E5135yzz
BCM in VIA Package PCB (Board) Mount Package Mechanical Drawing
5
6
7
8
9
4
3
2
13
OTPVIEW
BTOMSIDE
C(PMNTOIDSE)
0
1
2
1
BCM® in a VIA Package
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BCM in VIA Package PCB (Board) Mount Package Recommended Hole Pattern
'
SDETI'LA
4
3
A
9
8
7
6
5
EDATIL
3
12
MCDHOLPTARNE
1
10
2
1
BCM® in a VIA Package
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Revision History
Revision
1.0
Date
Description
Page Number(s)
03/3/16
05/2/16
06/17/16
08/01/16
09/26/16
Initial release
n/a
All
1.1
New Power Pin Nomenclature
Notes update
1.2
2, 3, 10
13, 14, 15
25
1.3
Charts format update
1.4
Value of R correction for READ_BCM_ROUT
Content improvements
Pin Finish Update
All
17
1.5
1.6
12/13/16
03/23/17
PMBus Supported Commands update
26 – 37
Package drawing update
39 – 41
Updated hi side voltage initialization threshold
6
1.7
01/16/18
Updated monitored telemetry technical information and lo side current spec
Updated mechanical drawings
10
38 – 40
BCM® in a VIA Package
Page 42 of 43
Rev 1.7
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BCM4414xD1E5135yzz
Vicor’s comprehensive line of power solutions includes high density AC-DC and DC-DC modules and
accessory components, fully configurable AC-DC and DC-DC power supplies, and complete custom
power systems.
Information furnished by Vicor is believed to be accurate and reliable. However, no responsibility is assumed by Vicor for its use. Vicor
makes no representations or warranties with respect to the accuracy or completeness of the contents of this publication. Vicor reserves
the right to make changes to any products, specifications, and product descriptions at any time without notice. Information published by
Vicor has been checked and is believed to be accurate at the time it was printed; however, Vicor assumes no responsibility for inaccuracies.
Testing and other quality controls are used to the extent Vicor deems necessary to support Vicor’s product warranty. Except where
mandated by government requirements, testing of all parameters of each product is not necessarily performed.
Specifications are subject to change without notice.
Visit http://www.vicorpower.com/dc-dc/isolated-fixed-ratio/hv-bus-converter-module for the latest product information.
Vicor’s Standard Terms and Conditions and Product Warranty
All sales are subject to Vicor’s Standard Terms and Conditions of Sale, and Product Warranty which are available on Vicor’s webpage
(http://www.vicorpower.com/termsconditionswarranty) or upon request.
Life Support Policy
VICOR’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE
EXPRESS PRIOR WRITTEN APPROVAL OF THE CHIEF EXECUTIVE OFFICER AND GENERAL COUNSEL OF VICOR CORPORATION. As used
herein, life support devices or systems are devices which (a) are intended for surgical implant into the body, or (b) support or sustain life and
whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to
result in a significant injury to the user. A critical component is any component in a life support device or system whose failure to perform
can be reasonably expected to cause the failure of the life support device or system or to affect its safety or effectiveness. Per Vicor Terms
and Conditions of Sale, the user of Vicor products and components in life support applications assumes all risks of such use and indemnifies
Vicor against all liability and damages.
Intellectual Property Notice
Vicor and its subsidiaries own Intellectual Property (including issued U.S. and Foreign Patents and pending patent applications) relating to the
products described in this data sheet. No license, whether express, implied, or arising by estoppel or otherwise, to any intellectual property
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The products described on this data sheet are protected by the following U.S. Patents Numbers:
Patents Pending
Contact Us: http://www.vicorpower.com/contact-us
Vicor Corporation
25 Frontage Road
Andover, MA, USA 01810
Tel: 800-735-6200
Fax: 978-475-6715
www.vicorpower.com
email
Customer Service: custserv@vicorpower.com
Technical Support: apps@vicorpower.com
©2018 Vicor Corporation. All rights reserved. The Vicor name is a registered trademark of Vicor Corporation.
The PMBus™ name, SMIF, Inc. and logo are trademarks of SMIF, Inc.
I2C™ is a trademark of NXP Semiconductor
All other trademarks, product names, logos and brands are property of their respective owners.
BCM® in a VIA Package
Page 43 of 43
Rev 1.7
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