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ELM611DA Schematic ( PDF Datasheet ) - ELM Technology

Teilenummer ELM611DA
Beschreibung high efficiency synchronous PWM step down DC/DC converter
Hersteller ELM Technology
Logo ELM Technology Logo 




Gesamt 11 Seiten
ELM611DA Datasheet, Funktion
ELM611DA 2A 23V
high efficiency synchronous PWM step down DC/DC converter
General description
ELM611DA is 350kHz fixed frequency PWM synchronous step-down regulator, whose input voltage can
be set within the range from 4.75V to 23V and output one is adjustable within the range from 0.923V to 18V;
maximum output current of ELM611DA can reach 2A. ELM611DA includes 2 switching MOSFETs whose ON
resistance is 85mΩ. Current mode control of ELM611DA makes it possible to provide fast transient response
and current protection of cycle-by-cycle. Shutdown current is Typ.1μA. Soft start is programmable by external
capacitor during start and limits inrush current to the appropriate value. ELM611DA is equipped with thermal
shutdown protection.
■Features
• Programmable soft start
• Short circuit protection
• Thermal shutdown protection
• Input voltage
: 4.75V to 23V
• Output voltage
: 0.923V to 18V
• Output current
: 2A
• High efficiency
: Max.93%
• Power MOSFET switches : 85mΩ
• Shutdown current
: Typ.1µA
• Fixed frequency
: Typ.350kHz
• Package
: SOP-8
■Application
• Distributed power system
• Network system
• FPGA, DSP, ASIC power supply
• Laptop
• Domestic appliance
■Maximum absolute ratings
Parameter
Symbol
Limit
VIN power supply voltage
Vin -0.3 to +24
Apply voltage to SW
Vsw GND-0.3 to Vin+0.3
Apply voltage to BS
Vbs Vsw-0.3 to Vsw+6
Apply voltage to FB
Vfb -0.3 to +6
Apply voltage to COMP
Vcomp
-0.3 to +6
Apply voltage to EN
Ven -0.3 to Vin+0.3
Apply voltage to SS
Vss -0.3 to +6
Power dissipation
Pd 630
Operating temperature range
Top
-40 to +85
Storage temperature range
Tstg -65 to +150
Caution:Permanent damage to the device may occur when ratings above maximum absolute ones are used.
Unit
V
V
V
V
V
V
V
mW
°C
°C
■Selection guide
ELM611DA-N
Symbol
a Package
b Product version
c Taping direction
* Taping direction is one way.
D: SOP-8
A
N: Refer to PKG file
ELM611DA - N
↑↑ ↑
ab c
11 - 1
Rev.1.2






ELM611DA Datasheet, Funktion
ELM611DA 2A 23V
high efficiency synchronous PWM step down DC/DC converter
necessary since the input switching current is absorbed by input capacitor (Cin). RMS of input current can be
calculated by following formula:
Icin = Iload × [ (Vout/Vin) × (1 − Vout/Vin) ]1/2
In worst case, when Vin = 2Vout, Icin = Iload/2. It is necessary to select capacitors which tolerate RMS ripple
current that is half of maximum load current. For input capacitors, ELM recommends using electrolytic, tan-
talum or ceramic ones. When using electrolytic or tantalum capacitors, please connect the 0.1μF one which is
high quality with high frequency to the IC as close as possible. When using ceramic capacitors, it is necessary
to provide sufficient capacity to prevent ripple voltage of input . Input voltage ripple for low ESR capacitors can
be calculated by following formula:
ΔVin = [ Iload/(Cin × fs) ] × (Vout/Vin) × (1 − Vout/Vin)
Cin=input capacitance value.
6. Capacitor
Capacitors are used to ensure output voltage of DC; ELM recommends using ceramic, tantalum, or low ESR
electrolytic ones. To keep output voltage ripple low, low ESR capacitors are preferable. Output voltage ripple
can be calculated by following formula:
ΔVout = [ Vout/(fs × L) ] × (1 − Vout/Vin) × [ Resr + 1 / (8 × fs × Cout) ]
Cout=output capacitance value; Resr=equivalent series resistance (ESR) value of the output capacitor.
When using ceramic capacitors, please select by the high frequency impedance capacitance of switching fre-
quency; output voltage ripple is mainly determined by capacitance. Output voltage ripple can be calculated by
following formula:
ΔVout = [ Vout/(8 × fs2 × L × Cout) ] × (1 − Vout/Vin)
When using tantalum or electrolytic capacitors, please select by ESR, which is mainly determined by imped-
ance of switching frequency. Output ripple can be calculated by following formula:
ΔVout = [ Vout/(fs × L) ] × (1 − Vout/Vin) × Resr
Stability of DC/DC converter would be effected by capacitance of output capacitor. ELM611DA is designed to
provide wide range of capacitance and stable operation of ESR.
7. Compensation components
ELM611DA realizes simple compensation and fast transient response by adopting current mode control;
COMP, which is output of internal transconductance error amplifier, controls system stability and transient re-
sponse. A capacitor and a resistor in series connection sets a pole-zero combination for compensation. DC gain
of voltage feedback loop can be calculated by following formula:
Avdc = Rload × Gcs × Aea × Vfb/Vout
Aea=error amplifier voltage gain; Gcs=current sense transconductance; Rload=load resistor value
The control loop has two important poles; one is the product of compensation capacitor (C1) and output resis-
tor of error amplifier, and the other one is the product of output capacitor and load resistor.
These poles are located at:
fp1 = Gea / (2π × C1 × Aea), fp2 = 1 / (2π × Cout × Rload)
Gea=error amplifier transconductance
Control system is produced by compensation capacitor (C1) and compensation resistor (R3), and has one zero.
This zero is located at:
fz1 = 1 / (2π × C1 × R3)
11 - 6
Rev.1.2

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