STMICROELECTRONICS TSM101AC

TSM101/A
VOLTAGE AND CURRENT CONTROLLER
■ 1.24V SERIES VOLTAGE REFERENCE
■
■
■
■
WITH 10mA OUTPUT CURRENT AND 1%
PRECISION (TSM101A)
TWO OPERATIONAL AMPLIFIERS WITH
ORED OUTPUT AND 1MHZ GAIN BANDWIDTH PRODUCT
BUILT-IN CURRENT GENERATOR WITH
ENABLE/DISABLE FUNCTION
4.5 TO 32V SUPPLY VOLTAGE RANGE
SO8 AND DIP8 PACKAGES
N
DIP8
(Plastic Package)
DESCRIPTION
The TSM101/TSM101A integrated circuit incorporates a high stability series band gap voltage reference, two ORed operational amplifiers and a current source.
This IC compares the DC voltage and the current
level at the output of a switching power supply to
an internal reference. It provides a feedback
through an optocoupler to the PWM controller IC
in the primary side.
The controlled current generator can be used to
modify the level of current limitation by offsetting
the information coming from the current sensing
resistor.
APPLICATIONS
PIN CONNECTIONS (top view)
This circuit is designed to be used in battery
chargers with a constant voltage and a limited output current.
It can be used in every types of application requiring a precision voltage regulation and current limitation.
Other applications include voltage supervisors,
over voltage protection...
ORDER CODE
Part Number
TSM101C/AC
TSM101I/AI
D
SO8
(Plastic Micropackage)
Temperature
Range
-20°C, +80°C
-40°C, +105°C
Package
N
D
•
•
•
•
1
Vref
8
2
7
3
6
4
5
N = Dual in Line Package (DIP)
D = Small Outline Package (SO) - also available in Tape & Reel (DT)
June 2001
1/13
TSM101/A
ABSOLUTE MAXIMUM RATINGS
Symbol
VCC
Parameter
Value
Unit
36
V
DC supply Voltage1)
2)
Iout
Output Current
20
mA
Pd
Power Dissipation
200
mW
Vin
Input Voltage3)
-0.3, VCC -1.5
V
Iout
Input Current
±1
mA
Tstg
Storage Temperature
Tj
Tthja
1.
2.
3.
-40 to +125
°C
150
°C
130 to 200
°C/W
Value
Unit
4.5 to 32
Tmax to Tmin
V
Maximum Junction Temperature
Thermal Resistante Junction to Ambiant
All voltages values, except differential voltage are with respect to network ground terminal.
The voltage reference is not protected against permanent short circuit.
The magnitude of input and output voltages must never exceed -0.3V or VCC -1.5V.
OPERATING CONDITIONS
Symbol
Parameter
VCC
Supply Voltage
Toper
Operating Free Air Temperature Range
ELECTRICAL CHARACTERISTICS
Tamb = 25°C, VCC = 15V (unless otherwise specified)
OPERATIONAL AMPLIFIER: TSM101C/I/AC/AI
Symbol
Parameter
Min.
ICC
Total Supply Current
VCC = 1.5V
Vi
Input Voltage Range
0
Vio
Input Offset Voltage
25°C
Tmin. ≤ Tamb ≤ Tmax.
-5
-7
Iib
Input Bias Current
@ Vin =1.2V on pin and Vin =0V on pin 5
25°C
Tmin. ≤ Tamb ≤ Tmax.
-700
-1000
15
SVR
Supply Voltage Rejection Ratio
Tmin. ≤ Tamb ≤ Tmax.
65
CMR
Common Mode Rejection Ratio
Tmin. ≤ Tamb ≤ Tmax.
GBP
Gain Bandwith Product
Vcc =15V, F = 100kHz
Vin = 10mV, RL = 2kΩ, CL = 100pF
2/13
Output Leakage Current
25°C
Tmin. ≤ Tamb ≤ Tmax.
1
VCC - 1.5V
V
5
7
mV
nA
Large Signal Voltage Gain
RL =2kΩ
Tmin. ≤ Tamb ≤ Tmax.
Io
Unit
mA
8
Avo
Max.
2
Output Sink Current, Vol =2.5V
25°C
Tmin. ≤ Tamb ≤ Tmax.
Isink
Typ.
-300
0
0
mA
15
V/m
V
dB
90
dB
80
1
MHz
2
7
µA
TSM101/A
ELECTRICAL CHARACTERISTICS
Tamb = 25°C, VCC = 15V (unless otherwise specified)
VOLTAGE REFERENCE : TSM101
TSM101C
Symbol
Vref
Kvt
Reglo
Regli
TSM101I
Parameter
Reference Voltage
Iout = 1mA, Tamb = 25°C
Unit
Min.
Typ.
Max.
Min.
Typ.
Max.
1.21
1.24
1.27
1.21
1.24
1.27
30
100
35
120
5
15
5
15
3.5
10
3.5
10
V
Temperature Stability
Tmin ≤Tamb ≤ Tmax
Load Regulation
1 < Iout < 10mA
Line Regulation
5 < Vin < 32V
ppm/°C
mV
mV
VOLTAGE REFERENCE : TSM101A
TSM101AC
Symbol
Vref
Kvt
Reglo
Regli
TSM101AI
Parameter
Reference Voltage
Iout = 1mA, Tamb = 25°C
Unit
Min.
Typ.
Max.
Min.
Typ.
Max.
1.227
1.24
1.252
1.227
1.24
1.252
30
100
35
120
5
15
5
15
3.5
10
3.5
10
V
Temperature Stability
Tmin ≤Tamb ≤ Tmax
Load Regulation
1 < Iout < 10mA
Line Regulation
5 < Vin < 32V
ppm/°C
mV
mV
CURRENT GENERATOR: TSM101, TSM101A
TSM101C/AC
Symbol
Unit
Min.
Io
Kcgt
Cglir
Vcsen
Vcsdis
Icsen
Icsleak
TSM101I/AI
Parameter
Current Source
Temperature Stability
Tmin ≤Tamb ≤ Tmax
Line Regulation
4.5 < Vcc< 32V
Voltage at the enable pin to have
Io = 1.4mA
Tmin ≤Tamb ≤ Tmax
Voltage at the enable pin to have
Io = 0mA
Tmin ≤Tamb ≤ Tmax
Input Current on the Csen pin
Tmin ≤Tamb ≤ Tmax
Leakage Current
Vcs = 2V
Tmin ≤Tamb ≤ Tmax
Typ.
Max.
Min.
Typ.
1.4
1.4
500
600
0.003
0.03
0.003
Max.
mA
ppm/°C
0.03
mA
V
0.6
0.6
V
2
2
µA
30
30
µA
0.5
2
0.5
2
3/13
TSM101/A
DESCRIPTION
Name
Pin
Type
Vref
1
OUTPUT
Vrin
7
INPUT
Voltage Regulation Loop input
Crin
5
INPUT
Current Limitation Loop Input, connected to the sense resisto
Crref
3
INPUT
Current Limitation Reference Input
Csen
2
INPUT
OUTPUT
6
OUTPUT
Vcc
8
INPUT
Power Supply Input (4.5 to 32V DC)
GND
4
INPUT
Ground
4/13
Function
Voltage Reference Output 1.24V, 10mA max. Do not short circuit
Current source enable input. This current source can be used to offset the
voltage measurement on the sense resistor and therefore to modify the
charge current. The current source enabled when the input voltage on pin 2
is lower than 0.8V.
Output pin common to the voltage regulation and current limitation loops.
This output can drive the primary side (LED) of an optocoupler.
APPLICATION NOTE
A BATTERY CHARGER USING THE TSM101
This technical note shows how to use the TSM101
integrated circuit with a switching mode power
supply (SMPS) to realize a battery charger.
An example of realization of a 12V Nickel-cadmium battery charger is given.
The galvanic insulation of the control information
is done by using an opto-coupler in linear mode
with a variable photo current depending on the difference between the actual output voltage and the
desired one.
1 - TSM101 PRESENTATION
A current limitation is used to protect the power
supply against short circuits, but lacks precision.
This limitation is generally realized by sensing the
current of the power transistor, in the primary side
of the SMPS.
The TSM101 integrated circuit incorporates a high
stability series band gap voltage reference, two
ORed operational amplifiers and a current source
(Figure 1)
The role of the TSM101 is to make a fine regulation of the output current of the SMPS and a precise voltage limitation.
Figure 1 : TSM101 Schematic Diagram
1
Vref
8
2
7
3
6
4
5
This IC compares the DC voltage and the current
level at the output of a switching power supply to
an internal reference.It provides a feedback
through an optocoupler to the PWM controller IC
in the primary side.
The controlled current generator can be used to
modify the level of current limitation by offsetting
the information coming from the current sensing
resistor.
A great majority of low or medium end power supplies is voltage regulated by using shunt programmable voltage references like the TL431
(Figure 2).
The primary current limitation is conserved and
acts as a security for a fail-safe operation if a
short-circuit occurs at the output of the charger.
2 - PRINCIPLE OF OPERATION
The current regulation loop and the voltage limitation loop use an internal 1.24V band-gap voltage
reference. This voltage reference has a good precision (better than 1.5%) and exhibits a very stable
temperature behavior.
The current limitation is performed by sensing the
voltage across the low ohmic value resistor R5
and comparing it to a fixed value set by the bridge
composed by R2 and R3 (Figure 3).
When the voltage on R5 is higher than the voltage
on R3 the output of the current loop operational
amplifier decreases. The optocoupler current increases and tends to reduce the output voltage by
the way of the PWM controller.
The voltage regulation is done by comparing a
part of the output voltage (resistor bridge R6, R7
and P1) to the voltage reference (1.24V).
If this part is higher than 1.24V, the output of the
voltage loop operational amplifier decreases.
5/13
TSM101/A
Figure 2 : SMPS Using a TL431 as Voltage Controller
The optocoupler current increases and tends to
reduce the output voltage by the way of the PWM
controller.
By enabling the TSM101 current source (pin 2) it
is possible to offset the current sensing by a voltage equal to :
Voff # R4 * Io with Io = 1.4mA
This offset lowers the output charge current and
this function can be used to charge two types of
batteries having different capacities. The current
source is enabled by connecting pin 2 to ground
3 - CALCULATION OF THE ELEMENTS
The charge current is regulated at 700mA (if the
charge control input is left open) or 200mA (if the
charge control input is put to ground ), allowing the
charge of two different types of batteries.
3.1 - Voltage limitation
The end-of- charge voltage is limited at 1.45V/cell,
this is the recommended voltage for an ambient
temperature at 25oC.
A diode is generally inserted at the output of the
charger to avoid the discharge of the battery if the
charger is not powered. This diode is sometimes
directly integrated in the battery pack. The influence of this diode on the charge is negligible if the
voltage drop (0.7V) is taken into account during
the design of the charger.
The voltage at the output of the charger is :
Vref
• R6=  -------------------------------- × R7
Vout – Vref
P1, which is a part of R6 and R7 is not considered
in this equation.
The following values are used on the application
board :
• R7 = 12kΩ
• R6 = 1kΩ
• P1 = 220Ω, adjust for V output = 15.2V with the
battery replaced by a 1kΩ resistor
• R10 = short circuit
• C3 = 100nF
3.2 - Current regulation
R5 is the sense resistor used for current measurement.
The current regulation is effective when the voltage drop across R5 is equal to the voltage on pin
5 of the TSM101 (assuming that the internal current source is disabled).
For medium currents (<1A), a voltage drop across
R5 of 200mV = Vr5 is a good value, R5 can be realized with standard low cost 0.5W resistors in
parallel.
Vr5
• R5 = ---------- , R5 = 0.285Ω (four 1.2Ω resistor in
Ich
parallel)
R2 and R3 can be chosen using the following formula :
Vref – Vr5
• R2 = R3 ×  ----------------------------
V r5
R6 + R 7
• Vout = ---------------------- × V r
R6
and regarding R6 and R7 :
6/13
CHARGE CONTROL
If the pin 2 is left open, the charge current is nominal at # 700mA.
TSM101/A
If pin 2 is connected to ground, the internal current
source is enabled, the current measurement is
off-setted by a voltage equal to :
• Vr4 = Io x R4 with Io = 1.4mA
This can be used to lower the charging current or
eventually to stop the charge, if Vr4 > V r5
In our example, the current offset is equal to 700 200mA = 500mA, representing a voltage offset
Vr4 = 140mV across R4.
The following values are used on the application
board :
• R5 = 4 *1.2Ω 0.5W in parallel
• R4 = 100Ω
• R2 = 1.2kΩ
• R3 = 220Ω
• R9 = short circuit
• R1 = 10kΩ
• C2 = 100nF
• C5 = 100nF
• C1 = output capacitor of the SMPS
• C4 = 10µF
4 - SCHEMATIC DIAGRAM
Figure 2 represents a schematic of the output circuit of a “classical” SMPS using a TL431 for voltage regulation. This circuit is modified to use
theTSM101 and the final circuit is represented in
figure 3.
Figure 3 : SMPS Using the TSM101
5 - IMPROVEMENT
5.1. High frequency compensation
Two R-C devices (R9 + C2 & R10 + C3) are used
to stabilize the regulation at high frequencies.
The calculation of these values is not easy and is
a function of the transfer function of the SMPS.
A guess value for the capacitors C2 and C3 is
100nF.
iary winding is added at the secondary side of the
transformer.
This winding is forward coupled to the primary
winding, the voltage across it is directly proportional to the mains rectified voltage, even if the flyback voltage is close to zero.
5.2. Power supply for TSM101
As this auxiliary winding is a voltage source, it is
necessary to add a resistor (R11) on the cathode
of the rectifier (D3) to limit the current.
In applications requiring low voltage battery
charge or when the charger is in current regulation
mode, the output voltage can be too low to supply
correctly the TSM101.
The same problem occurs when the output is
short-circuited.
A solution to provide a quasi constant supply voltage to the TSM101 is shown at figure 4 : an auxil-
A low cost regulator (Q2 and Zener diode D4) is
used to power the TSM101. This is necessary with
autoranging SMPS with wide input voltages, for
example 90 to 240V without switching. In standard
SMPS with voltage range from 200 to 240VAC or
100 to 130VAC, this regulator can be removed
and replaced by the small power supply shown on
figure 5 (Raux, Caux, D2).
7/13
TSM101/A
Figure 4 : An Auxiliary Winding for TSM101 Power Supply
5.3. Higher Precision for the Voltage Control
The voltage drop through the sense resistor R5
offsets the voltage measurement. In most battery
charging applications, this offset is not taken into
account because the error is negligeable compared to the end-of-charge voltage due to the fact
that the charging current value decreases drastically during the final phase of the battery charging.
But in other applications needing highest possible
precision in voltage control, another connecting
schematic is possible for TSM101 as shown on
figure 5.
Figure 5 : Precise Output Voltage Control
In this schematic, the 0V reference is defined as
the common point between the sense resistor, the
0V Output Voltage, the foot of the resistor bridge
8/13
R6/R7, and the ground (pin 4) of the TSM101.
TSM101A (1% internal voltage reference precision) is required in such applications.
TSM101/A
5.4. An example of application where the
charging current is different according to the
charging phase.
The following application includes a specific recommendation which requires that the charging
current should be fixed to Ich1 = 800mA in normal
charging conditions, and Ich2 = 200mA when the
cell voltage is below Vl=2.5V to optimize the cell
life-time.
Moreover, an Charging Status LED should be
switched off when the cell voltage is above
Vh=6.5V.
Figure 6 shows how this can easily be achieved
using an additional dual comparator (type LM393)
where the first operator (C1) is used to activate the
TSM101 internal current generator to offset the
current measurement thanks to R4, and the second (C2) is used to switch the status LED off. On
figure 6, the status signal is determined by voltage
measurement, this could as well be achieved by
current measurement.
If V5 = 100mV is the maximum tolerable voltage
drop through the sense resistor R5 during normal
charging conditions, then the following calculations apply :
Current Control :
R5 = V5 / Ich1 = 0.1 / 0.8 = 0.125
R5 = 125mΩ
V5 = Vref x R3 / (R2 + R3) with R2 + R3 ~ 12kΩ
and Vref = 1.24V
R3 = 1kΩ, R2 = 11.4kΩ
V5 = R4 x Io + R5 x Ich2, therefore, R4 = (V5 - R5
x Ich2) / Io with Io = 1.4mA
R4 = 53.6Ω
Vref = Vl x R15 / (R14 + R15) with Vl = 2.5V and
R14 + R15 ~ 20kΩ
R15 = R14 = 10kΩ
Voltage Control :
Vref = Vh x R6 / (R6 + R7) with Vh = 6.5V and
R6 + R7 ~ 12kW
R6 = 2.36kW, R7 = 10kW
Vref = Vh R17 / (R16 + R17)
R17 = 10kW, R16 = 42kW
Voltage Control :
Vref = Vh x R6 / (R6 + R7) with Vh = 6.5V and
R6 + R7 ~ 12kW
R6 = 2.36kW, R7 = 10kW
Vref = Vh R17 / (R16 + R17)
R17 = 10kW, R16 = 42kW
Figure 6 : Optimized Charging Conditions
9/13
EVALUATION BOARD -TECHNICAL NOTE
TSM101 integrates in the same 8 pin DIP or SO
package
• one 1.24V precision voltage reference
• two operationnal amplifiers
• two diodes which impose a NOR function on the
outputs of the operationnal amplifiers
• one current source which can be activated/ inhibited thanks to an external pin.
An immediate way to take advantage of the high
integration and reliability of TSM101 is to use it as
a voltage and current controller on power supplies
secondary. The application note AN896 describes
precisely how to use TSM101 in an SMPS battery
charger.
The TSM101 Evaluation Board is adaptable to any
power supply or battery charger (SMPS or linear)
as a voltage and current controller with minimal
constraints from the user.
The “IN+”and “IN-” power inputs of the evaluation board should be connected directly to the
power lines of the power supply secondary.
The “Vcc” input of the evaluation board should
be connected to the auxiliary supply line.
In the case of an SMPS power supply, the “Reg”
output of the evaluation board should be connected to the Optocoupler input to regulate the PWM
block in the primary side. In the case of a linear
power supply, the “Reg” output should be connected to the base of the darlington to regulate the
power output.
A diode might be needed on the output of the evaluation board in the case of a battery charger application to avoid the discharge of the battery when
the charger is not connected.
HOW TO USE THE TSM101 EVALUATION
BOARD ?
The voltage control is given by the choice of the
resistor bridge R6/R7 (and the trimmer P1) due to
equation 1 :
• Vref = R6/(R6+R7)xVout
eq1
where Vref = 1.24V
The generic Electrical Schematic is shown on figure 1. It represents an incomplete SMPS power
supply where the primary side is simplified.
Figure 1
10/13
COMPONENTS CALCULATIONS
TSM101/A
The current control is given by the choice of the
voltage drop through the sense resistor R5 (to be
linked to the nominal current of the application)
and by the value of the sense resistor itself.
For medium currents (< 1A), a good value for the
voltage drop through R5 can be Vsense = 200mV
(dissipation < 200mW).
The resistor bridge R2/R3 should be chosen following equation 2 :
• Vsense = R3/(R2+R3)xVref
eq2
The total value of the resistor bridge should be in
the range of the kW in order to ensure a proper
charge for the voltage reference (in the range of
the mA).
To set the current limit, the sense resistor R5
should be chosen following equation 3 :
• Ilim = Vsense/R5
eq3
The internal current generator (Isce) can be used
to offset the current limitation with a lower value.
This current generator is activated by connecting
pin 2 to ground. It is inhibited if pin 2 is connected
to the positive rail via the pull up resistor R1.
The current offset is given by the choice of the resistor R4.
If Ilim1 is the current limit calculated in the previous paragraph, and Ilim2 is the current limit that is
to be set when pin 2 is connected to ground, R4
should be chosen following equation 4 :
• R4 = (Vsense - Ilim2xR5)/Isce
eq4
where Isce = 1.4mA
C4 and C5 are bypass capacitors used to smoothen the regulated outputs.
C2 and C3 are capacitors used for high frequency
compensation.
Voltage/
Current
Control
R1
R2
R3
R4
R5
R6
R7
P1
2 straps
C2
C3
C4
C5
15V
700mA
200mA
12V
1A
500mA
8.2V
200mA
100mA
10kΩ
1.2kΩ
220kΩ
100Ω
1.2Ω x 4
1kΩ
12kΩ
100Ω
0Ω
100nF
100nF
10µF
100nF
10kΩ
1.2kΩ
220kΩ
68Ω
0.8Ω x 4
1kΩ
8.2kΩ
100Ω
0Ω
100nF
100nF
22µF
100nF
10kΩ
1.2kΩ
220kΩ
68Ω
1Ω x 1
1kΩ
5.6kΩ
100Ω
0Ω
100nF
100nF
4.7µF
100nF
Figure 2
EXAMPLES OF COMPONENT LISTS
Table 1 summerizes a few examples of component lists to generate quickly 15V/700mA/200mA,
12V/1A/500mA or 8.2V/200mA/100mA voltage
and current regulations.
11/13
TSM101/A
PACKAGE MECHANICAL DATA
8 PINS - PLASTIC DIP
Millimeters
Inches
Dim.
Min.
A
a1
B
b
b1
D
E
e
e3
e4
F
i
L
Z
12/13
Typ.
Max.
Min.
3.32
0.51
1.15
0.356
0.204
0.020
0.045
0.014
0.008
0.065
0.022
0.012
0.430
0.384
0.313
2.54
7.62
7.62
3.18
Max.
0.131
1.65
0.55
0.304
10.92
9.75
7.95
Typ.
0.100
0.300
0.300
6.6
5.08
3.81
1.52
0.125
0260
0.200
0.150
0.060
TSM101/A
PACKAGE MECHANICAL DATA
8 PINS - PLASTIC MICROPACKAGE (SO)
s
b1
b
a1
A
a2
C
c1
a3
L
E
e3
D
M
5
1
4
F
8
Millimeters
Inches
Dim.
Min.
A
a1
a2
a3
b
b1
C
c1
D
E
e
e3
F
L
M
S
Typ.
Max.
0.65
0.35
0.19
0.25
1.75
0.25
1.65
0.85
0.48
0.25
0.5
4.8
5.8
5.0
6.2
0.1
Min.
Typ.
Max.
0.026
0.014
0.007
0.010
0.069
0.010
0.065
0.033
0.019
0.010
0.020
0.189
0.228
0.197
0.244
0.004
45° (typ.)
1.27
3.81
3.8
0.4
0.050
0.150
4.0
1.27
0.6
0.150
0.016
0.157
0.050
0.024
8° (max.)
Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences
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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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13/13