ROHM BD3538HFN

High Performance Regulators for PCs
Termination Regulators
for DDR-SDRAMs
BD3538F,BD3538HFN
No.10030EAT33
Description
BD3538F/HFN is a termination regulator compatible with JEDEC DDR-SDRAM, which functions as a linear power supply
incorporating an N-channel MOSFET and provides a sink/source current capability up to 1A respectively. A built-in
high-speed OP-AMP specially designed offers an excellent transient response. Requires 3.3 volts or 5.0 volts as a bias
power supply to drive the N-channel MOSFET. Has an independent reference voltage input pin (VDDQ) and an
independent feedback pin (VTTS) to maintain the accuracy in voltage required by JEDEC, and offers an excellent output
voltage accuracy and load regulation. Also has a reference power supply output pin (VREF) for DDR-SDRAM or a memory
controller. When EN pin turns to “Low”, VTT output becomes “Hi-Z” while VREF output is kept unchanged, compatible with
“Self Refresh” state of DDR-SDRAM.
Features
1) Incorporates a push-pull power supply for termination (VTT)
2) Incorporates a reference voltage circuit (VREF)
3) Incorporates an enabler
4) Incorporates an undervoltage lockout (UVLO)
5) Employs SOP8 package
6) Employs HSON8 package
7) Incorporates a thermal shutdown protector (TSD)
8) Operates with input voltage from 2.7 to 5.5 volts
9) Compatible with Dual Channel (DDR-II)
Use
Power supply for DDR I / II / III - SDRAM
●Absolute Maximum Ratings
Parameter
Input Voltage
Enable Input Voltage
Symbol
Ratings
Unit
BD3538F
BD3538HFN
VCC
7 *1*2
7 *1*2
V
VEN
7
*1*2
7
*1*2
V
*1*2
7
*1*2
V
7 *1*2
V
Termination Input Voltage
VTT_IN
7
VDDQ Reference Voltage
VDDQ
7 *1*2
Output Current
ITT
1
1
A
Power Dissipation1
Pd1
560 *3
630 *5
mW
Power Dissipation2
Pd2
690 *4
1350 *6
mW
*7
mW
Power Dissipation3
Pd3
-
Operating Temperature Range
Tstg
-40～+105
-40～+105
1750
℃
Storage Temperature Range
Tjmax
-55～+150
-55～+150
℃
Maximum Junction Temperature
Tjmax
+150
+150
℃
*1 Should not exceed Pd.
*2 Instantaneous surge voltage, back electromotive force and voltage under less than 10% duty cycle.
*3 Reduced by 4.48mW for each increase in Ta of 1℃ over 25℃(With no heat sink).
*4 Reduced by 5.52mW for each increase in Ta of 1℃ over 25℃(When mounted on a board 70mm×70mm×1.6mm Glass-epoxyPCB).
*5 Reduced by 5.04mW/℃ for each increase in Ta≧25℃ (when mounted on a 70mm×70mm×1.6mm glass-epoxy board, 1-layer)
On less than 0.2% (percentage occupied by copper foil.
*6 Reduced by 10.8mW/℃ for each increase in Ta≧25℃ (when mounted on a 70mm×70mm×1.6mm glass-epoxy board, 1-layer)
On less than 7.0% (percentage occupied by copper foil.
*7 Reduced by 14.0mW/℃ for each increase in Ta≧25℃ (when mounted on a 70mm×70mm×1.6mm glass-epoxy board, 1-layer)
On less than 65.0% (percentage occupied by copper foil.
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1/10
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Operating Conditions (Ta=25℃)
Parameter
Input Voltage
Ratings
Symbol
Min
Max
2.7
5.5
VCC
Unit
V
Termination Input Voltage
VTT_IN
1.0
5.5
V
VDDQ Reference Voltage
VDDQ
1.0
2.75
V
VEN
-0.3
5.5
V
Enable Input Voltage
★ No radiation-resistant design is adopted for the present product.
●Electrical Characteristics (unless otherwise noted, Ta=25℃ VCC=3.3V VEN=3V VDDQ=1.8V VTT_IN=1.8V)
Limits
Condition
Parameter
Symbol
Unit
Min
Typ
Max
Standby Current
IST
-
0.5
1.0
mA
VEN=0V
Bias Current
[Enable]
ICC
-
2
4
mA
VEN=3V
High Level Enable Input Voltage
VENHIGH
2.3
-
5.5
V
Low Level Enable Input Voltage
VENLOW
-0.3
-
0.8
V
IEN
-
7
10
µA
Termination Output Voltage 1
VTT1
VREF-30m
VREF
VREF+30m
V
Termination Output Voltage 2
VTT2
VREF-30m
VREF
VREF+30m
V
Source Current
ITT+
1.0
-
-
A
Sink Current
ITT-
-
-
-1.0
A
⊿VTT
-
-
50
mV
20
40
mV
Enable Pin Input Current
[Termination]
Load Regulation
Reg.l
-
Upper Side ON Resistance 1
HRON1
-
0.45
0.9
Ω
Lower Side ON Resistance 1
LRON1
-
0.45
0.9
Ω
Upper Side ON Resistance 2
HRON2
-
0.4
0.8
Ω
Lower Side ON Resistance 2
LRON2
-
0.4
0.8
Ω
ZVDDQ
70
100
130
kΩ
Line Regulation
VEN=3V
ITT=-1.0A to 1.0A
*6
Ta=0℃ to 105℃
VCC=5V, VDDQ=2.5V
VTT_IN=2.5V
ITT=-1.0A to 1.0A
Ta=0℃ to 105℃ *6
ITT=-1.0A to 1.0A
VCC=5V, VDDQ=2.5V
VTT_IN=2.5V
VCC=5V, VDDQ=2.5V
VTT_IN=2.5V
[Reference Voltage Input]
Input Impedance
Output Voltage 1
VREF1
Output Voltage 2
VREF2
1/2×VDDQ
1/2×VDDQ
1/2×VDDQ
-18m
+18m
1/2×VDDQ
1/2×VDDQ
1/2×VDDQ
-40m
+40m
Output Voltage 3
VREF3
1/2×VDDQ
1/2×VDDQ
1/2×VDDQ
-25m
+25m
V
Output Voltage 4
VREF4
1/2×VDDQ
1/2×VDDQ
1/2×VDDQ
-40m
+40m
V
V
V
IREF=-5mA to 5mA
Ta=0℃ to 105℃*6
IREF=-10mA to 10mA
*6
Ta=0℃ to 105℃
VCC=5V, VDDQ=2.5V
VTT_IN=2.5V
IREF=-5mA to 5mA
Ta=0℃ to 105℃ *6
VCC=5V, VDDQ=2.5V
VTT_IN=2.5V
ITT=-10mA to 10mA
Ta=0℃ to 105℃ *6
[UVLO]
Threshold Voltage
VUVLO
2.40
2.55
2.70
V
Hysteresis Voltage
⊿VUVLO
100
160
220
mV
VCC : sweep up
VCC : sweep down
*6 Design Guarantee
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2/10
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Reference Data
VTT(20mV/Div)
VTT(20mV/Div)
ITT(1A/Div)
ITT(1A/Div)
10µsec/Div
VTT(20mV/Div)
ITT(1A/Div)
10µsec/Div
10µsec/Div
Fig.2 DDR1 (1A→-1A)
Fig.1 DDR1 (-1A→1A)
Fig.3 DDR2 (-1A→1A)
1.252
0.902
0.901
VREF(V)
ITT(1A/Div)
VREF(V)
1.251
VTT(20mV/Div)
1.250
1.249
10µsec/Div
0.899
0.898
1.248
-10
-5
0
IREF(mA)
5
10
0.897
-10
-5
0
IREF(mA)
5
10
Fig.6 IREF-VREF (DDR2)
Fig.5 IREF-VREF (DDR1)
Fig.4 DDR2 (1A→-1A)
0.900
0.920
1.260
0.915
VCC
0.910
1.255
VTT(V)
VTT(V)
0.905
1.250
EN
0.900
0.895
VDDQ
VTT IN
0.890
1.245
0.885
VTT
0.880
1.240
-2
-1
0
ITT(A)
1
2
Fig.7 ITT-VTT (DDR1)
-2
-1
0
ITT(A)
1
Fig.8 ITT-VTT (DDR2)
2
Fig.9 Input Sequence 1
VTT_IN
VCC
VCC
EN
EN
VDDQ
VTT IN
VDDQ
VTT IN
VTT
VTT
Fig.10 Input Sequence 2
Fig.11 Input Sequence 3
VTT
VREF
1234
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ITT_IN
(1A/div)
3/10
Fig.12 Start up Wave Form
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Block Diagram
VTT_IN
VDDQ
VCC
VCC
VTT_IN
VDDQ
6
5
VCC
7
VCC
VCC
UVLO
SOFT
Reference
Block
TSD
EN
UVLO
UVLO
Thermal
VCC
TSD
EN
UVLO
EN
VTT
TSD
EN
UVLO
TSD
3
Protection
Enable
VTT
8
VTTS
½×
VDDQ
4
EN
VREF
2
1
GND
●PIN Configration
●PIN Function
PIN No. PIN Name
GND 1
EN 2
GND
GND Pin
2
EN
3
VTTS
Detector Pin for Termination Voltage
4
VREF
Reference Voltage Output Pin
5
VDDQ
Reference Voltage Input Pin
6
VCC
7
VTT_IN
8
VTT
Termination Output Pin
Bottom
FIN
Substraight
(Conntct to GND)
Enable Input Pin
7 VTT_IN
6 VCC
VREF 4
5 VDDQ
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1
8 VTT
VTTS 3
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PIN Function
4/10
VCC Pin
Termination Input Pin
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Description of operations
・VCC
In BD3538F/HFN, an independent power input pin is provided for an internal circuit operation of the IC. This is used to
drive the amplifier circuit of the IC, and its maximum current rating is 4 mA. The power supply voltage is 3.3 to 5.5 volts.
It is recommended to connect a bypass capacitor of 1 µF or so to VCC.
・VDDQ
Reference input pin for the output voltage, that may be used to satisfy the JEDEC requirement for DDR-SDRAM (VTT =
1/2VDDQ) by dividing the voltage inside the IC with two 50 kΩ voltage-divider resistors
For BD3538F/HFN, care must be taken to an input noise to VDDQ pin because this IC also cuts such noise input into half
and provides it with the voltage output divided in half. Such noise may be reduced with an RC filter consisting of such
resistance and capacitance (220 Ω and 2.2 µF, for instance) that may not give significant effect to voltage dividing inside
the IC.
・VTT_IN
VTT_IN is a power supply input pin for VTT output. Voltage in the range between 1.0 and 5.5 volts may be supplied to
this VTT_IN terminal, but care must be taken to the current limitation due to on-resistance of the IC and the change in
allowable loss due to input/output voltage difference.
Generally, the following voltages are supplied:
・ DDR I
VTT_IN=2.5V
・ DDRII
VTT_IN=1.8V
・ DDRIII
VTT_IN=1.5V
Higher impedance of the voltage input at VTT_IN may result in oscillation or degradation in ripple rejection, which must be
noted. To VTT_IN terminal, it is recommended to use a 10 µF capacitor characterized with less change in capacitance.
But it may depend on the characteristics of the power supply input and the impedance of the pc board wiring, which must
be carefully checked before use.
・VREF
In BD3538F/HFN, a reference voltage output pin independent from VTT output is given to provide a reference input for a
memory controller and a DRAM. Even if EN pin turns to “Low” level, VREF output is kept unchanged, compatible with
“Self Refresh” state of DRAM. The maximum current capability of VREF is 20 mA, and a suitable capacitor is needed to
stabilize the output voltage. It is recommended to use a combination of a 1.0 to 2.2 µF ceramic capacitor characterized
with less change in capacitance and a 0.5 to 2.2 Ω phase compensator resistor, or a 10µF ceramic or tantalum capacitor
instead. For an application where VREF current is low, a capacitor of lower capacitance may be used. If VREF current
is 1 mA or less, it is possible to secure a phase margin with a ceramic capacitor of 1 µF more or less.
・VTTS
An independent pin provided to improve load regulation of VTT output. In case that longer wiring is needed to the load at
VTT output, connecting VTTS from the load side may improve the load regulation.
・VTT
A DDR memory termination output pin. BD3538F/HFN has a sink/source current capability of ±1.0A respectively. The
output voltage tracks the voltage divided in half at VDDQ pin. VTT output is turned to OFF when VCC UVLO or thermal
shutdown protector is activated with EN pin level turned to “Low”. Do not fail to connect a capacitor to VTT output pin for
a loop gain phase compensation and a reduction in output voltage variation in the event of sudden change in load.
Insufficient capacitance may cause an oscillation. High ESR (Equivalent Series Resistance) of the capacitor may result
in increase in output voltage variation in the event of sudden change in load. It is recommended to use a 220 µF
functional polymer capacitor (OS-CON, POS-CAP, NEO-CAP), though it depends on ambient temperature and other
conditions. A low ESR ceramic capacitor may reduce a loop gain phase margin and may cause an oscillation, which may
be improved by connecting a resistor in series with the capacitor.
・EN
With an input of 2.3 volts or higher, the level at EN pin turns to “High” to provide VTT output. If the input is lowered to 0.8
volts or less, the level at EN pin turns to “Low” and VTT status turns to Hi-Z. But if VCC and VDDQ are established,
VREF output is maintained.
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5/10
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Evaluation Board
■ BD3538F/HFN Evaluation Board Circuit
VCC
GND
U1
EN
SW1
GND
BD3538F/HFN
2
VTT_IN
VDDQ
C5
R4
J2
7
8
5
3
C9
VTT
VTTS
C7
VREF
4
6
VCC
C2
C3
1
■ BD3538F/HFN Evaluation Board Application Components
Part No
Value
Company
Parts Name
U1
-
ROHM
BD3538F/HFN
R4
220Ω
ROHM
MCR032200
J1
0Ω
-
C2
10µF
MURATA
GRM21 Series
C3
1µF
MURATA
GRM18 Series
C5
10µF
MURATA
GRM21 Series
C7
220µF
SANYO
2R5TPE220MF
C9
2.2µF
MURATA
GRM18 Series
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-
6/10
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Notes for use
1. Absolute maximum ratings
For the present product, thoroughgoing quality control is carried out, but in the event that applied voltage, working
temperature range, and other absolute maximum rating are exceeded, the present product may be destroyed. Because
it is unable to identify the short mode, open mode, etc., if any special mode is assumed, which exceeds the absolute
maximum rating, physical safety measures are requested to be taken, such as fuses, etc.
2. GND potential
Bring the GND terminal potential to the minimum potential in any operating condition.
3. Thermal design
Consider allowable loss (Pd) under actual working condition and carry out thermal design with sufficient margin provided.
4. Terminal-to-terminal short-circuit and erroneous mounting
When the present IC is mounted to a printed circuit board, take utmost care to direction of IC and displacement. In the
event that the IC is mounted erroneously, IC may be destroyed. In the event of short-circuit caused by foreign matter that
enters in a clearance between outputs or output and power-GND, the IC may be destroyed.
5. Operation in strong electromagnetic field
The use of the present IC in the strong electromagnetic field may result in maloperation, to which care must be taken.
6. Built-in thermal shutdown protection circuit
The present IC incorporates a thermal shutdown protection circuit (TSD circuit). The working temperature is 175°C
(standard value) and has a -15°C (standard value) hysteresis width. When the IC chip temperature rises and the TSD
circuit operates, the output terminal is brought to the OFF state. The built-in thermal shutdown protection circuit (TSD
circuit) is first and foremost intended for interrupt IC from thermal runaway, and is not intended to protect and warrant the
IC. Consequently, never attempt to continuously use the IC after this circuit is activated or to use the circuit with the
activation of the circuit premised.
7. Capacitor across output and GND
In the event a large capacitor is connected across output and GND, when Vcc and VIN are short-circuited with 0V or GND
for some kind of reasons, current charged in the capacitor flows into the output and may destroy the IC. Use a capacitor
smaller than 1000 µF between output and GND.
8. Inspection by set substrate
In the event a capacitor is connected to a pin with low impedance at the time of inspection with a set substrate, there is a
fear of applying stress to the IC. Therefore, be sure to discharge electricity for every process. As electrostatic
measures, provide grounding in the assembly process, and take utmost care in transportation and storage. Furthermore,
when the set substrate is connected to a jig in the inspection process, be sure to turn OFF power supply to connect the jig
and be sure to turn OFF power supply to remove the jig.
9. Inputs to IC terminals
+
This device is a monolithic IC with P isolation between P-substrate and each element as illustrated below. This P-layer
and the N-layer of each element form a PN junction which works as:
・a diode if the electric potentials at the terminals satisfy the following relationship; GND>Terminal A>Terminal B, or
・a parasitic transistor if the electric potentials at the terminals satisfy the following relationship; Terminal B>GND Terminal A.
The structure of the IC inevitably forms parasitic elements, the activation of which may cause interference among circuits,
and/or malfunctions contributing to breakdown. It is therefore requested to take care not to use the device in such
manner that the voltage lower than GND (at P-substrate) may be applied to the input terminal, which may result in
activation of parasitic elements.
Resistor
Transistor (NPN)
Pin A
Pin B
C
Pin A
N
P+
N
P+
P
Parasitic element
E
N
P+
N
P substrate
GND
Pin B
B
N
P+
P
B
C
N
E
Parasitic
element
P substrate
Parasitic element
GND
GND
Parasitic element
Other
adjacent
elements
GND
10. GND wiring pattern
When both a small-signal GND and high current GND are present, single-point grounding (at the set standard point) is
recommended, in order to separate the small-signal and high current patterns, and to be sure the voltage change
stemming from the wiring resistance and high current does not cause any voltage change in the small-signal GND. In the
same way, care must be taken to avoid wiring pattern fluctuations in any connected external component GND.
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7/10
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
11. Output capacitor (C1)
Do not fail to connect a output capacitor to VREF output terminal for stabilization of output voltage. The capacitor
connected to VREF output terminal works as a loop gain phase compensator. Insufficient capacitance may cause an
oscillation. It is recommended to use a low temperature coefficient 1-10 µF ceramic capacitor, though it depends on
ambient temperature and load conditions. It is therefore requested to carefully check under the actual temperature and
load conditions to be applied.
12. Output capacitor (C4)
Do not fail to connect a capacitor to VTT output pin for stabilization of output voltage. This output capacitor works as a loop
gain phase compensator and an output voltage variation reducer in the event of sudden change in load. Insufficient
capacitance may cause an oscillation. And if the equivalent series resistance (ESR) of this capacitor is high, the variation
in output voltage increases in the event of sudden change in load. It is recommended to use a 47-220 µF functional
polymer capacitor, though it depends on ambient temperature and load conditions. Using a low ESR ceramic capacitor may
reduce a loop gain phase margin and cause an oscillation, which may be improved by connecting a resistor in series with
the capacitor. It is therefore requested to carefully check under the actual temperature and load conditions to be applied.
13. Input capacitors (C2 and C3)
These input capacitors are used to reduce the output impedance of power supply to be connected to the input terminals
(VCC and VTT_IN). Increase in the power supply output impedance may result in oscillation or degradation in ripple rejecting
characteristics. It is recommended to use a low temperature coefficient 1µF (for VCC) and 10µF (for VTT_IN) capacitor,
but it depends on the characteristics of the power supply input, and the capacitance and impedance of the pc board wiring
pattern. It is therefore requested to carefully check under the actual temperature and load conditions to be applied.
14. Input terminals (VCC, VDDQ, VTT_IN and EN)
VCC, VDDQ, VTT_IN and EN terminals of this IC are made up independent one another. To VCC terminal, the UVLO
function is provided for malfunction protection. Irrespective of the input order of the inputs terminals, VTT output is
activated to provide the output voltage when UVLO and EN voltages reach the threshold voltage while VREF output is
activated when UVLO voltage reaches the threshold. If VDDQ and VTT_IN terminals have equal potential and common
impedance, any change in current at VTT_IN terminal may result in variation of VTT_IN voltage, which affects VDDQ
terminal and may cause variation in the output voltage. It is therefore required to perform wiring in such manner that
VDDQ and VTT_IN terminals may not have common impedance. If impossible, take appropriate corrective measures
including suitable CR filter to be inserted between VDDQ and VTT_IN terminals.
15. VTTS terminal
A terminal used to improve load regulation of VTT output. Connection with VTT terminal must be done not to have
common impedance with high current line, which may offer better load regulation of VTT output.
16. Operating range
Within the operating range, the operation and function of the circuits are generally guaranteed at an ambient temperature
within the range specified. The values specified for electrical characteristics may not be guaranteed, but drastic change
may not occur to such characteristics within the operating range.
17. Allowable loss Pd
For the allowable loss, the thermal derating characteristics are shown in the Exhibit, which should be used as a guide.
Any uses that exceed the allowable loss may result in degradation in the functions inherent to IC including a decrease in
current capability due to chip temperature increase. Use within the allowable loss.
18. Built-in thermal shutdown protection circuit
Thermal shutdown protection circuit is built-in to prevent thermal breakdown. Turns VTT output to OFF when the thermal
shutdown protection circuit activates. This thermal shutdown protection circuit is originally intended to protect the IC itself.
It is therefore requested to conduct a thermal design not to exceed the temperature under which the thermal shutdown
protection circuit can work.
19. The use in the strong electromagnetic field may sometimes cause malfunction, to which care must be taken.
In the event that load containing a large inductance component is connected to the output terminal, and generation of
back-EMF at the start-up and when output is turned OFF is assumed, it is requested to insert a protection diode.
20. In the event that load containing a large inductance component is connected to (Example)
the output terminal, and generation of back-EMF at the start-up and when
OUTPUT PIN
output is turned OFF is assumed, it is requested to insert a protection diode.
21. We are certain that examples of applied circuit diagrams are recommendable,
but you are requested to thoroughly confirm the characteristics before using the
IC.In addition, when the IC is used with the external circuit changed, decide the
IC with sufficient margin provided while consideration is being given not only to
static characteristics but also variations of external parts and our IC including
transient characteristics.
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8/10
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Heat Loss
Thermal design must be conducted with the operation under the conditions listed below (which are the guaranteed
temperature range requiring consideration on appropriate margins etc.):
1. Ambient temperature Ta: 100°C or lower
2. Chip junction temperature Tj: 150°C or lower
The chip junction temperature Tj can be considered as follows. See Page 2/10 for θja.
For the package has FIN at the bottoms of IC, package power depends on the connected copper foil area. Be sure to keep
the board surface area or release the heat with setting enough through holes to inside pattern.
Most of heat loss in BD3538F/HFN occurs at the output N-channel FET. The power lost is determined by multiplying the
voltage between VIN and Vo by the output current. As this IC employs the power PKG, the thermal derating characteristics
significantly depends on the pc board conditions. When designing, care must be taken to the size of a pc board to be used.
Power dissipation (W) = {Input voltage (VTT_IN) – Output voltage (VTT=1/2VDDQ)}×Io (Ave)
If VTT_IN = 1.8 volts, VDDQ=1.8 volts, and Io (Ave)=0.5 A, for instance, the power dissipation is determined as follows:
Power dissipation (W) = {1.8 (V) – 0.9 (V)} × 0.5 (A) = 0.4 (W)
●Power Dissipation
◎SOP8
◎HSON8
2.0
800
(1) 690mW
600
(1) 1.75W
Power Dissipation ：Pd （W)
Power Dissipation ：Pd （mW)
700
(2) 560mW
500
400
100℃
300
200
100
1.5
(2) 1.35W
1.0
(3) 0.63W
0.5
0.0
0
0
25
50
75
100
125
0
150
Ambient Temperature：Ta(℃)
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50
75
100
125
150
Ambient Temperature：Ta(℃)
(1) 1 layer (copper foil density : 65％）
θja=71.4℃/W
(2) 1 layer (copper foil density : 7％)
θja=92.4℃/W
(3) 1 layer (copper foil density : 0.2％)
θja=198.4℃/W
(1) 70mm×70mm×1.6mm Glass-epoxy PCB
θj-c=181℃/W
(2) With no heat sink
θj-a=222℃/W
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25
9/10
2010.05 - Rev.A
Technical Note
BD3538F,BD3538HFN
●Ordering part number
B
D
3
Part No.
5
3
8
Part No.
H
F
N
-
Package
F
: SOP8
HFN : HSON8
T
R
Packaging and forming specification
E2: Embossed tape and reel
(SOP8)
TR: Embossed tape and reel
(HSON8)
SOP8
<Tape and Reel information>
5.0±0.2
(MAX 5.35 include BURR)
6
+6°
4° −4°
5
6.2±0.3
4.4±0.2
0.3MIN
7
1 2
3
0.9±0.15
8
Tape
Embossed carrier tape
Quantity
2500pcs
Direction
of feed
E2
The direction is the 1pin of product is at the upper left when you hold
( reel on the left hand and you pull out the tape on the right hand
)
4
0.595
1.5±0.1
+0.1
0.17 -0.05
S
S
0.11
0.1
1.27
Direction of feed
1pin
0.42±0.1
Reel
(Unit : mm)
∗ Order quantity needs to be multiple of the minimum quantity.
HSON8
<Tape and Reel information>
2.90±0.2
0.6MAX.
1PIN MARK
3000pcs
5 6 78
Direction
of feed
(0.30)
(0.15)
(0.45)
(0.2)
(0.2) (1.8)
2.80±0.2
3.00± 0.2
12 34
Embossed carrier tape
Quantity
(2.2) (0.05)
0.475
87 6 5
Tape
4321
TR
The direction is the 1pin of product is at the upper right when you hold
( reel on the left hand and you pull out the tape on the right hand
+0.1
0.13 –0.05
)
1pin
0.32±0.10
0.65
Direction of feed
Reel
(Unit : mm)
www.rohm.com
© 2010 ROHM Co., Ltd. All rights reserved.
10/10
∗ Order quantity needs to be multiple of the minimum quantity.
2010.05 - Rev.A
Notice
Notes
No copying or reproduction of this document, in part or in whole, is permitted without the
consent of ROHM Co.,Ltd.
The content specified herein is subject to change for improvement without notice.
The content specified herein is for the purpose of introducing ROHM's products (hereinafter
"Products"). If you wish to use any such Product, please be sure to refer to the specifications,
which can be obtained from ROHM upon request.
Examples of application circuits, circuit constants and any other information contained herein
illustrate the standard usage and operations of the Products. The peripheral conditions must
be taken into account when designing circuits for mass production.
Great care was taken in ensuring the accuracy of the information specified in this document.
However, should you incur any damage arising from any inaccuracy or misprint of such
information, ROHM shall bear no responsibility for such damage.
The technical information specified herein is intended only to show the typical functions of and
examples of application circuits for the Products. ROHM does not grant you, explicitly or
implicitly, any license to use or exercise intellectual property or other rights held by ROHM and
other parties. ROHM shall bear no responsibility whatsoever for any dispute arising from the
use of such technical information.
The Products specified in this document are intended to be used with general-use electronic
equipment or devices (such as audio visual equipment, office-automation equipment, communication devices, electronic appliances and amusement devices).
The Products specified in this document are not designed to be radiation tolerant.
While ROHM always makes efforts to enhance the quality and reliability of its Products, a
Product may fail or malfunction for a variety of reasons.
Please be sure to implement in your equipment using the Products safety measures to guard
against the possibility of physical injury, fire or any other damage caused in the event of the
failure of any Product, such as derating, redundancy, fire control and fail-safe designs. ROHM
shall bear no responsibility whatsoever for your use of any Product outside of the prescribed
scope or not in accordance with the instruction manual.
The Products are not designed or manufactured to be used with any equipment, device or
system which requires an extremely high level of reliability the failure or malfunction of which
may result in a direct threat to human life or create a risk of human injury (such as a medical
instrument, transportation equipment, aerospace machinery, nuclear-reactor controller, fuelcontroller or other safety device). ROHM shall bear no responsibility in any way for use of any
of the Products for the above special purposes. If a Product is intended to be used for any
such special purpose, please contact a ROHM sales representative before purchasing.
If you intend to export or ship overseas any Product or technology specified herein that may
be controlled under the Foreign Exchange and the Foreign Trade Law, you will be required to
obtain a license or permit under the Law.
Thank you for your accessing to ROHM product informations.
More detail product informations and catalogs are available, please contact us.
ROHM Customer Support System
http://www.rohm.com/contact/
www.rohm.com
© 2010 ROHM Co., Ltd. All rights reserved.
R1010A