IK3051

TECHNICAL DATA
Constant Voltage and Constant Current Controller
for Adaptors and Battery Chargers
IK3051
Description
IK3051 is a highly integrated solution for SMPS applications
requiring constant voltage and constant current mode.
IK3051 integrates one voltage reference, two operational amplifiers
(with ORed outputs – common collectors), and a current sensing circuit.
The voltage reference combined with one operational amplifier
makes it an ideal voltage controller, and the other low voltage reference
combined with the other operational amplifier makes it an ideal current
limiter for output low side current sensing.
The current threshold is fixed and precise.
The only external components are:
• A resistor bridge to be connected to the output of the power supply
(adapter, battery charger) to set the voltage regulation by dividing
the desired output voltage to match the internal voltage reference
value.
• A sense resistor having a value and allowable dissipation power
which need to be chosen according to the internal voltage threshold.
• Optional compensation components (R and C).
IK3051, is ideal for smallest package available, is ideal for space
shrinked applications such as adapters and battery chargers.
PIN CONNECTION (top view)
Features
•
•
•
•
•
•
CONSTANT VOLTAGE AND CONSTANT CURRENT
CONTROL
LOW VOLTAGE OPERATION
PRECISION INTERNAL COMPONENT COUNT
CURRENT SINK OUTPUT STAGE
EASY COMPENSATION
LOW AC MAINS VOLTAGE REJECTION
ORDERING INFORMATION
Device
IK3051S2T
Operating
Temperature Range
TA = 0° to 85° C
for all packages
Package
Plastic
SOT23-6
Shipping
Tape& Reel
Pin Definitions and Functions
SOT23-6 Pin out
Name
Vcc
GND
Vctrl
Ictrl
Out
Vsense
Pin#
6
2
1
4
3
5
Type
Power Supply
Power Supply
Analog Input
Analog Input
Current Sink Output
Analog Input
Function
Positive Power Supply Line
Ground Line. 0V Reference For All Voltages
Input Pin of the Voltage Control Loop
Input Pin of the Current Control Loop
Output Pin. Sinking Current Only
Input Pin of the Current Control Loop
July 2009, Ver.01
IK3051
Absolute Maximum Ratings
Symbol
Vcc
Vi
Top
Tj
Parameter
DC Supply Voltage
Input Voltage
Operating Free Air Temperature Range
Maximum Junction Temperature
Value
14
-0.3 to Vcc
0 to 85
150
Unit
V
V
o
C
o
C
Operation Conditions
Symbol
Vcc
Parameter
DC Supply Conditions
Value
2.5 to 12
Unit
V
Electrical Characteristics
Tamb = 25°C and Vcc = +5V (unless otherwise specified)
Symbol
Parameter
Total Current Consumption
Total Supply Current – not taking the
Icc
output sinking current into account
Voltage Control Loop
Transconduction Gain (Vctrl). Sink
Gmv
1)
Current Only
Vref
Voltage Control Loop Reference
Iibv
Input Bias Current (Vctrl)
2)
Current Control Loop
Transconduction Gain (Ictrl). Sink
Gmi
3)
Current Only
4)
Vsense
Current Control Loop Reference
Iibi
Current out of pin Ictrl at -200mV
Output Stage
Low output voltage at 10 mA sinking
Vol
current
Output Short Circuit Current. Output
Ios
to Vcc. Sink Current Only
Test Condition
Min
Tamb
0 < Tamb < 85°C
Tamb
0 < Tamb < 85°C
Tamb
0 < Tamb < 85°C
Tamb
0 < Tamb < 85°C
Tamb
0 < Tamb < 85°C
Iout = 2.5 mA Tamb
0 < Tamb < 85°C
Tamb
0 < Tamb < 85°C
Tamb
0 < Tamb < 85°C
Tamb
0 < Tamb < 85°C
Typ
Max
1.1
1.2
2
1
3.5
2.5
1.198
1.186
1.21
Unit
mA
mA/mV
1.222
1.234
V
50
100
nA
1.5
7
mA/mV
196
192
200
204
208
mV
25
50
µA
200
mV
27
35
50
mA
1. If the voltage on Vctrl (the negative input of the amplifier) is higher than the positive amplifier input (Vref=1.210V),
and it is increased by 1mV, the sinking current at the output OUT will be increased by 3.5mA.
2. The internal Voltage Reference is set at 1.210V (bandgap reference). The voltage control loop precision takes into
account the cumulative effects of the internal voltage reference deviation as well as the input offset voltage of the
trans-conductance operational amplifier. The internal Voltage Reference is fixed by bandgap, and trimmed to 1%
accuracy at room temperature.
3. When the positive input at Ictrl is lower than -200mV, and the voltage is decreased by 1mV, the sinking current at the
output OUT will be increased by 7mA.
4. The internal current sense threshold is set to -200mV. The current control loop precision takes into account the
cumulative effects of the internal voltage reference deviation as well as the input offset voltage of the transconduction operational amplifier.
July 2009, Ver.01
IK3051
PRINCIPLE OF OPERATION AND APPLICATION HINTS
1. Voltage and Current Control
1.1. Voltage Control
The voltage loop is controlled via a first
transconductance operational amplifier, the resistor
bridge R1, R2, and the optocoupler which is directly
connected to the output.
The relation between the values of R1 and R2
should be chosen as written in Equation 1.
R1 = R2 x Vref / (Vout - Vref)
Eq1
Where Vout is the desired output voltage.
To avoid the discharge of the load, the resistor
bridge R1, R2 should be highly resistive. For this
type of application, a total value of 100KΩ (or
more) would be appropriate for the resistors R1
and R2.
As an example, with R2 = 100KΩ, Vout = 4.10V,
Vref = 1.210V, then R1 = 41.9KΩ.
Note that if the low drop diode should be inserted
between the load and the voltage regulation
resistor bridge to avoid current flowing from the
load through the resistor bridge, this drop should
be taken into account in the above calculations by
replacing Vout by (Vout + Vdrop).
function which ensures that whenever the current
or the voltage reaches too high values, the
optocoupler is activated.
The relation between the controlled current and the
controlled output voltage can be described with a
square characteristic as shown in the following V/I
output-power graph.
Figure 1 : Output voltage versus output current
2. Compensation
1.2. Current Control
The current loop is controlled via the second transconductance operational amplifier, the sense
resistor Rsense, and the optocoupler.
The control equation verifies:
Rsense x Ilim = Vsense
eq2
Rsense = Vsense / Ilim
eq2’
where Ilim is the desired limited current, and
Vsense is the threshold voltage for the current
control loop.
As an example, with Ilim = 1A, Vsense = -200mV,
then Rsense = 200mΩ.
Note that the Rsense resistor should be chosen
taking into account the maximum dissipation (Plim)
through it during full load operation.
Plim = Vsense x Ilim.
eq3
As an example, with Ilim = 1A, and Vsense =
200mV, Plim = 200mW.
Therefore, for most adapter and battery charger
applications, a quarter-watt, or half-watt resistor to
make the current sensing function is sufficient.
Vsense threshold is achieved internally by a
resistor bridge tied to the Vref voltage reference. Its
middle point is tied to the positive input of the
current control operational amplifier, and its foot is
to be connected to lower potential point of the
sense resistor as shown on the following figure.
The resistors of this bridge are matched to provide
the best precision possible.
The current sinking outputs of the two transconductance operational amplifiers are common
(to the output of the IC). This makes an ORing
The voltage-control trans-conductance operational
amplifier can be fully compensated. Both of its
output and negative input are directly accessible for
external compensation components.
An example of a suitable compensation network is
shown in Fig.2. It consists of a capacitor
Cvc1=2.2nF and a resistor Rcv1=470KΩ in series,
connected in parallel with another capacitor
Cvc2=22pF.
The current-control trans-conductance operational
amplifier can be fully compensated. Both of its
output and negative input are directly accessible for
external compensation components.
An example of a suitable compensation network is
shown in Fig.2. It consists of a capacitor
Cic1=2.2nF and a resistor Ric1=22KΩ in series.
When the Vcc voltage reaches 12V it could be
interesting to limit the current coming through the
output in the aim to reduce the dissipation of the
device and increase the stability performances of
the whole application.
An example of a suitable Rout value could be
330Ω in series with the opto-coupler in case
Vcc=12V.
3. Start Up and Short Circuit Conditions
Under start-up or short-circuit conditions the
IK3051 is not provided with a high enough supply
voltage. This is due to the fact that the chip has its
July 2009, Ver.01
IK3051
power supply line in common with the power supply
line of the system.
Therefore, the current limitation can only be
ensured by the primary PWM module, which
should be chosen accordingly.
If the primary current limitation is considered not to
be precise enough for the application, then a
sufficient supply for the IK3051 has to be ensured
under any condition. It would then be necessary to
add some circuitry to supply the chip with a
separate power line. This can be achieved in
numerous ways, including an additional winding on
the transformer.
The following schematic shows how to realize a
low-cost power supply for the IK3051 (with no
additional windings).
Please pay attention to the fact that in the particular
case presented here, this low-cost power supply
can reach voltages as high as twice the voltage of
the regulated line. Since the Absolute Maximum
Rating of the IK3051 supply voltage is 14 V, this
low-cost auxiliary power supply can only be used in
applications where the regulated line voltage does
not exceed 7 V.
Figure 2 : Typical Adapter or Battery Charger Application Using IK3051
In
the above application schematic, the IK3051 is used on the secondary side of a flyback adapter (or battery
charger) to provide an accurate control of voltage and current. The above feedback loop is made with an
optocoupler.
July 2009, Ver.01
IK3051
Typical Application
Figure 3
July 2009, Ver.01
IK3051
Typical Application (continue)
Figure 4
July 2009, Ver.01
IK3051
Typical Application (continue)
Figure 5
July 2009, Ver.01
IK3051
Typical Performance Characteristics
Figure 6: Vref vs Ambient Temperature
Figure 7: Vsense pin input bias current vs
Ambient Temperature
Figure 8: Output short circuit current vs
Ambient Temperature
Figure 9: Vsense vs Ambient Temperature
Figure 10: Ictrl pin input bias current vs
Ambient Temperature
Figure 11: Supply current vs
Ambient Temperature
July 2009, Ver.01
IK3051
PACKAGE DIMENSION
SOT-23-6
Symbol
A
A1
A2
b
c
D
E
E1
e
e1
L
L1
θ
Dimensions In Millimeters
Min
1.050
0.000
1.050
0.300
0.100
2.820
1.500
2.650
Dimensions In Inches
Max
1.250
0.100
1.150
0.500
0.200
3.020
1.700
2.950
Min
0.041
0.000
0.041
0.012
0.004
0.111
0.059
0.104
2.000
0.071
0.600
8°
0.012
0°
0.950TYP
1.800
0.037TYP
0.600REF
0.300
0°
Max
0.049
0.004
0.045
0.020
0.008
0.119
0.067
0.116
0.079
0.024REF
0.024
8°
July 2009, Ver.01