STMICROELECTRONICS TSM1014IDT

TSM1014
Low Consumption Voltage and Current
Controller for Battery Chargers and Adaptors
■
■
■
■
■
■
■
■
Constant voltage and constant current
control
Low consumption
Low voltage operation
Low external component count
Current sink output stage
Easy compensation
High ac mains voltage rejection
2kV ESD protection (HBM)
D
SO-8
(Plastic Package)
Voltage Reference:
■
■
Fixed output voltage reference 1.25V
0.5% and 1% Voltage precision
S
MiniSO-8
(Plastic Micropackage)
DESCRIPTION
TSM1014 is a highly integrated solution for SMPS
applications requiring CV (constant voltage) and
CC (constant current) mode.
PIN CONNECTIONS (top view)
TSM1014 integrates one voltage reference and
two operational amplifiers.
The voltage reference combined with one
operational amplifier makes it an ideal voltage
controller. The other operational amplifier,
combined with few external resistors and the
voltage reference, can be used as a current
limiter.
1 Vref
Vcc
8
2 Cc-
Cc Out 7
3 Cc+
Gnd 6
4 Cv-
Cv Out 5
APPLICATIONS
■
Adapters
■
Battery chargers
ORDER CODES
Part Number
TSM1014ID
TSM1014IDT
TSM1014AID
TSM1014AIDT
TSM1014IST
TSM1014AIST
July 2004
Temperature Range
Package
SO-8
-40 to 105°C
mini SO-8
Revision 1
Packaging
VRef (%)
Marking
Tube
Tape & Reel
Tube
Tape & Reel
Tape & Reel
Tape & Reel
1
1
0.5
0.5
1
0.5
M1014
M1014
M1014A
M1014A
M808
M809
1/10
TSM1014
1
Pin Descriptions
Pin Descriptions
The table below gives the pin descriptions for both SO8 & MiniSO8 packages.
Name
VRef
CCCC+
CVCVOUT
Gnd
CCOUT
Vcc
2
Pin #
1
2
3
4
5
6
7
8
Type
Function
Analog Output
Analog Input
Analog Input
Analog Input
Analog Output
Power Supply
Analog Output
Power Supply
Voltage Reference
Input pin of the operational amplifier
Input pin of the operational amplifier
Input pin of the operational amplifier
Output of the operational amplifier
Ground Line. 0V Reference For All Voltages
Output of the operational amplifier
Power supply line.
Absolute Maximum Ratings
Symbol
Vcc
Vi
PT
Toper
Tstg
Tj
Iref
ESD
Rthja
Rthja
3
DC Supply Voltage
DC Supply Voltage (50mA =< Icc)
Input Voltage
Power dissipation
Operational temperature
Storage temperature
Junction temperature
Voltage reference output current
Electrostatic Discharge
Thermal Resistance Junction to Ambient Mini SO8 package
Thermal Resistance Junction to Ambient SO8 package
Value
Unit
-0.3V to Vz
-0.3 to Vcc
0 to 105
-55 to 150
150
2.5
2
180
175
V
V
W
°C
°C
°C
mA
kV
°C/W
°C/W
Value
Unit
4.5 to Vz
-40 to 105
V
°C
Operating Conditions
Symbol
Vcc
Toper
2/10
Parameter
DC Supply Conditions
Operational temperature
Electrical Characteristics
4
TSM1014
Electrical Characteristics
Tamb = 25°C and Vcc = +18V (unless otherwise specified)
Symbol
Parameter
Test Condition
Min
Typ
Max
Unit
100
180
µA
Total Current Consumption
Icc
Vz
Total Supply Current, excluding current
in Voltage Reference1.
Vcc clamp voltage
Vcc = 18V, no load
Tmin. < Tamb < Tmax.
Icc = 50mA
28
V
Operator 1: Op-amp with non-inverting input connected to the internal VRef
VRef+Vio
DVio
Input Offset Voltage + Voltage reference Tamb = 25°C
TSM1014
Tmin. ≤ Tamb ≤ Tmax.
Tamb = 25°C
TSM1014A
Tmin. ≤ Tamb ≤ Tmax.
1.251
1.25
Input Offset Voltage Drift
1.266
1.279
1.258
1.267
V
µV/°C
7
Operator 2
Input Offset Voltage
TSM1014
Vio
DVio
TSM1014A
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
4
5
2
3
SVR
Supply Voltage Rejection Ration
VCC = 4.5V to 28V
Vicm
Input Common Mode Voltage Range
Common Mode Rejection Ratio
20
50
65
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
70
60
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
0.5
150
200
100
0
mV
µV/°C
7
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
CMR
0.5
Input Offset Voltage Drift
Input Bias Current
Iib
1
nA
dB
Vcc-1.5
85
V
dB
Output stage
Gm
Vol
Ios
Transconduction Gain. Sink Current
Only2
Low output voltage at 5 mA sinking current
Output Short Circuit Current. Output to
(Vcc-0.6V). Sink Current Only
Tmin. ≤ Tamb ≤ Tmax.
1
1
250
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
6
5
10
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
Tamb = 25°C
Tmin. ≤ Tamb ≤ Tmax.
1.238
1.225
1.244
1.237
1.25
mA/mV
400
mV
mA
Voltage reference
Reference Input Voltage
TSM1014 1% precision
VRef
TSM1014A 0.5% precision
Reference Input Voltage Deviation Over
Temperature Range
Reference input voltage deviation over
RegLine
Vcc range.
Reference input voltage deviation over
RegLoad
output current.
∆VRef
Tmin. ≤ Tamb ≤ Tmax.
1.25
20
Iload = 1mA
Vcc = 18V,
0 < Iload < 2.5mA
1.262
1.273
1.256
1.261
V
30
mV
20
mV
10
mV
1) Test conditions: pin 2 and 6 connected to GND, pin 4 and 5 connected to 1.25V, pin 3 connected to 200mV.
2) The current depends on the voltage difference between the negative and the positive inputs of the amplifier. If the voltage on the minus
input is 1mV higher than the positive amplifier, the sinking current at the output OUT will be increased by Gm*1mA.
3/10
TSM1014
Electrical Characteristics
Figure 1: Internal schematic
Vref
1
Vcc 8
Vref
28V
Cc-
2
Ccout
7
CC
Cc+
3
Gnd
CV
Cv-
4
Cvout
6
5
Figure 2: Typical adapter or battery charger application using TSM1014
Vcc
1
OUT+
D
8
Rlimit
To primary
Vcc
Vref
28V
DS
R2
IL
CV
R4
100K
3
CV Out
5
Cv-
4
Load
R3
100
+
TSM1014
Cc+
CC Out
CC
7
Rvc1
22K
+
Cc-
Gnd
R5 Vsense
10K
Rsense IL
6
+
2
CS
Ric2
1K
Ric1
Cvc1
2.2nF
R1
Cic1
2.2nF
22K
OUT-
In the application schematic shown in Figure 2, the TSM1014 is used on the secondary side of a flyback
adapter (or battery charger) to provide an accurate voltage and current control. The above feedback loop
is made with optocoupler.
4/10
Principles of Operation and Application Tips
5
TSM1014
Principles of Operation and Application Tips
5.1 Voltage control
The voltage loop is controlled via a first trans-conductance 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)
Equation 1
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 is 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).
5.2 Current control
The current loop is controlled via the second trans-conductance operational amplifier, the sense resistor
Rsense, and the optocoupler.
Vsense threshold is achieved externally 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 control equation verifies:
R sense × I lim = V sense
Equation 2
R 5 ⋅ V ref
V sense = ----------------------( R 4 + R5 )
R 5 ⋅ V ref ⋅ R sense
I lim = ---------------------------------------( R4 + R 5 )
Equation 3
where Ilim is the desired limited current, and Vsense is the threshold voltage for the current control loop.
Note that the Rsense resistor should be chosen taking into account the maximum dissipation (Plim)
through it during full load operation.
P lim = I lim × V sense
Equation 4
5/10
TSM1014
Principles of Operation and Application Tips
Therefore, for most adapter and battery charger applications, a quarter-watt, or half-watt resistor to make
the current sensing function is sufficient.
The current sinking outputs of the two trans-conductance operational amplifiers are common (to the
output of the IC). This makes an ORing 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 3: Output Voltage versus Output Current
Vout
Current regulation
Voltage regulation
0
TSM1014 Vcc : independent power supply
Secondary current regulation
Iout
TSM1014 Vcc : On power output
Primary current regulation
5.3 Compensation
The voltage-control trans-conductance operational amplifier can be fully compensated. Both its output
and negative input are directly accessible for external compensation components.
An example of a suitable voltage-control compensation network is shown in Figure 2 on page 4. It
consists of a capacitor Cvc1=2.2nF and a resistor Rcv1=22KΩ in series.
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 current-control compensation network is also shown in Figure 2 on page 4. It
consists of a capacitor Cic1=2.2nF and a resistor Ric1=22KΩ in series.
5.4 Start-up and short circuit conditions
Under start-up or short-circuit conditions the TSM1014 is not provided with a high enough supply voltage.
This is due to the fact that the chip has its 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 TSM1014 has to be ensured under all conditions. For this, it would be necessary to add
some circuitry to supply the chip with a separate power line. This can be achieved in a number of ways,
including putting an additional winding on the transformer.
6/10
Principles of Operation and Application Tips
TSM1014
5.5 Voltage clamp
The following schematic shows how to realize a low-cost power supply for the TSM1014 (with no
additional windings).Please pay attention to the fact that in the particular case presented here, this lowcost power supply can reach voltages as high as twice the voltage of the regulated line. Since the
Absolute Maximum Rating of the TSM1014 supply voltage is 28V. In the aim to protect he TSM1014
against such how voltage values a internal zener clamp is integrated.
R limit = ( V cc – V z ) ⋅ I vz
Figure 4: Clamp voltage
Vcc
Rlimit
Ivz
TSM1014
Vcc
Vz
28V
Figure 5: Voltage controller and over current detection schematic
OCP
8
CV
Vcc
R2
Vref
To primary
28V
CV Out
CV
5
22K
R4
100K
Cv-
4
IL
R6
1K
R3
1k
Rvc1
Load
1
OUT+
D
Cvc1
2.2nF
+
3
Cc+
CC Out
CC
7
R1
+
R5 Vsense
10K
Rsense IL
6
Gnd
2
Cc-
Ric2
1K
Ric1
Cic1
2.2nF
22K
OUT-
7/10
TSM1014
6
Package Mechanical Data
Package Mechanical Data
SO-8 MECHANICAL DATA
DIM.
mm.
MIN.
TYP
inch
MAX.
MIN.
TYP.
MAX.
A
1.35
1.75
0.053
0.069
A1
0.10
0.25
0.04
0.010
A2
1.10
1.65
0.043
0.065
B
0.33
0.51
0.013
0.020
C
0.19
0.25
0.007
0.010
D
4.80
5.00
0.189
0.197
E
3.80
4.00
0.150
0.157
e
1.27
0.050
H
5.80
6.20
0.228
0.244
h
0.25
0.50
0.010
0.020
L
0.40
1.27
0.016
0.050
k
ddd
8˚ (max.)
0.1
0.04
0016023/C
8/10
Package Mechanical Data
TSM1014
9/10
TSM1014
7
Revision History
Revision History
Date
Revision
01 July 2004
1
Description of Changes
First Release
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences
of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted
by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject
to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not
authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics.
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All other names are the property of their respective owners
© 2004 STMicroelectronics - All rights reserved
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