STMICROELECTRONICS L4990D

L4990
L4990A

PRIMARY CONTROLLER
CURRENT-MODE CONTROL PWM
SWITCHING FREQUENCY UP TO 1MHz
LOW START-UP CURRENT < 0.45mA
HIGH-CURRENT OUTPUT DRIVE SUITABLE
FOR POWER MOSFET (1A)
FULLY LATCHED PWM LOGIC WITH DOUBLE PULSE SUPPRESSION
PROGRAMMABLE DUTY CYCLE
100% AND 50% MAXIMUM DUTY CYCLE
LIMIT
PROGRAMMABLE SOFT START
PRIMARY OVERCURRENT FAULT DETECTION WITH RE-START DELAY
PWM UVLO WITH HYSTERESIS
IN/OUT SYNCHRONIZATION
DISABLE LATCHED
INTERNAL 100ns LEADING EDGE BLANKING OF CURRENT SENSE
PACKAGE: DIP16 AND SO16W
MULTIPOWER BCD TECHNOLOGY
DIP16
SO16W
ORDERING NUMBERS: L4990/L4990A(DIP16)
L4990D/L4990AD (SO16W)
line or DC-DC power supply applications using a
fixed frequency current mode control.
Based on a standard current mode PWM controller this device includes some features as programmable soft start, IN/OUT synchronization,
disable (to be used for over voltage protection
and for power management), precise maximum
Duty Cycle Control, 100ns (typ) leading edge
blanking on current sense, pulse by pulse current
limit and overcurrent protection with soft start intervention.
DESCRIPTION
This primary controller I.C., developed in BCD60II
technology, has been designed to implement off
BLOCK DIAGRAM
RCT
2
SYNC
DC-LIM
1
15
VCC
VREF
8
4
TIMING
25V
+
3
DC
14
-
DIS
Vref
+
16V/10V
T
PWM UVLO
-
9
DIS
VC
+
2.5V
13V
S
BLANKING
10
OUT
Q
R
PWM
OVER CURRENT
ISEN
13
1.2V
SS
FAULT
SOFT-START
+
VREF OK
CLK
DIS
11
2.5V
7
+
5
E/A
-
2R
1V
VFB
R
12
SGND
July 1999
PGND
6
COMP
D98IN1002
1/24
L4990 - L4990A
ABSOLUTE MAXIMUM RATINGS
Symbol
VCC
IOUT
Parameter
Supply Voltage (ICC < 50mA) (*)
Output Peak Pulse Current
Analog Inputs & Outputs (6,7)
Analog Inputs & Outputs (1,2,3,4,5,15,14 13)
Power Dissipation @ Tamb = 70°C
Junction Temperature, Operating Range
Storage Temperature, Operating Range
Ptot
Tj
Tstg
Value
selflimit
1.5
-0.3 to 8
-0.3 to 6
1
-25 to 125
-55 to 150
Unit
V
A
V
V
W
°C
°C
Value
80
120
Unit
°C/W
°C/W
(*) maximum package power dissipation limits must be observed
PIN CONNECTION
SYNC
1
16
N.C.
RCT
2
15
DC-LIM
DC
3
14
DIS
VREF
4
13
ISEN
VFB
5
12
SGND
COMP
6
11
PGND
SS
7
10
VCC
8
9
OUT
VC
D95IN197
THERMAL DATA
Symbol
Rth j-amb
Rth j-amb
Parameter
Thermal Resistance Junction to Ambient
Thermal Resistance Junction to Ambient
DIP16
SO16
PIN FUNCTIONS
N.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Name
SYNC
RCT
DC
VREF
VFB
COMP
SS
VCC
VC
OUT
PGND
SGND
ISEN
DIS
DC-LIM
16
NC
2/24
Function
Synchronization. A synchronization pulse terminates the PWM cycle and discharges Ct
Oscillator pin for external C t, Rt components
Duty Cycle control
5.0V +/-1.5% reference voltage
Error Amplifier Inverting input
Error Amplifier Output
Soft start pin for external capacitor Css
Supply for internal ”Signal” circuitry
Supply for Power section
High current totem pole output
Power ground
Signal ground
Current sense
Disable. It must never be left floating. Tie to SGND if not used.
Connecting this pin to Vref, DC is limited to 50%. If it is left floating or grounded no limitation is
imposed
Not connected
L4990 - L4990A
ELECTRICAL CHARACTERISTICS (VCC = 15V; Tj = 0 to 70°C; unless otherwise specified.)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
REFERENCE SECTION
VO
TS
IOS
Output Voltage
Tj = 25°C; IO = 1mA
5.0
5.075
V
Line Regulation
VCC = 12 to 20V
4.925
2.0
15
mV
Load Regulation
IO = 1 to 20mA
5.0
20
mV
Temperature Stability
0.4
Total Variation
Line, Load, Temperature
Short Circuit Current
Vref = 0V
Power Down/UVLO
VCC = 8.5V; Isink = 0.5mA
4.875
5.0
mV/°C
5.125
V
150
mA
0.2
0.5
V
30
OSCILLATOR SECTION
Initial Accuracy
Tj = 25°C; RT = 4.42kΩ;
C T = 1nF; pin 15 Vref
285
300
315
kHz
Accuracy
R T = 4.42KΩ; VCC = 12 to 20V;
C T = 1nF; pin 15 = Vref
279
300
321
kHz
Initial Accuracy
Tj = 25°C; RT = 4.42KΩ;
C T = 1nF; pin 15 OPEN
280
295
310
kHz
Accuracy
R T = 4.42KΩ; VCC = 12 to 20V;
C T = 1nF; pin 15 OPEN
275
295
315
kHz
Duty Cycle
pin 3 = 0,7V, pin 15 = Vref
pin 3 = 0.7V, pin 15 = OPEN
0
0
%
%
Duty Cycle
R T = 4.42kΩ CT = 1nF
pin 3 = 3.2V, pin 15 = Vref
pin 3 = 3.2V, pin 15 = OPEN
45
90
pin 3 = 2.02V, pin 15 = OPEN
37
Duty Cycle Accuracy
%
%
40
43
%
Oscillator Ramp Peak
3.0
V
Oscillator Ramp Valley
1.0
V
ERROR AMPLIFIER SECTION
Input Bias Current
VI
GOPL
VFB to GND
Input Voltage
VCOMP = VFB
Open Loop Gain
VCOMP = 2 to 4V
SVR
Supply Voltage Rejection
VCC = 12 to 20V
V OL
Output Low Voltage
Isink = 2mA, VFB = 2.7V
VOH
Output High Voltage
Isou rce = 0.5mA, VFB = 2.3V
Output Source Current
VCOMP > 4V, V FB = 2.3V
Output Sink Current
VCOMP = 1.1V, V FB = 2.7V
IO
Unit Gain Bandwidth
SR
0.2
1.0
2.42
2.5
2.58
60
90
µA
V
dB
85
dB
1.1
V
5
6
V
0.5
1.3
mA
2
6
mA
2
4
MHz
8
V/µs
Slew Rate
PWM CURRENT SENSE SECTION
Ib
Input Bias Current
Isen = 0
IS
Maximum Input Signal
VCOMP = 5V
0.92
Delay to Output
ISSC
SS Charge Current
ISSD
SS Discharge Current
VSS = 0.6V
VSSSAT
SS Saturation Voltage
DC = 0%
SS Clamp Voltage
15
µA
1.08
V
100
Gain
SOFT START
VSSCLAMP
3
1.0
ns
2.85
3
3.15
V/V
14
20
26
µA
0.6
µA
V
200
7
V
100
ns
LEADING EDGE BLANKING
Internal Masking Time
3/24
L4990 - L4990A
ELECTRICAL CHARACTERISTICS (continued.)
Symbol
Parameter
Test Condition
Min.
Typ.
Max.
Unit
1.0
V
OUTPUT SECTION
V OL
Output Low Voltage
IO = 250mA
VOH
Output High Voltage
IO = 20mA; VCC = 12V
10
10.5
V
IO = 200mA; VCC = 12V
9
10
V
VOUT CLAMP
Output Clamp Voltage
IO = 5mA; VCC = 20V
13
Collector Leakage
VCC = 20V VC = 24V
100
200
µA
Fall Time
C O = 1nF
C O = 2.5nF
20
35
60
ns
ns
Rise Time
C O = 1nF
C O = 2.5nF
50
70
100
ns
ns
1.0
V
UVLO Saturation
SUPPLY SECTION
VCC = 0V to VCCON; Isink = 10mA
V
VCCON
Startup voltage
L4990
L4990A
15
7.8
16
8.4
17
9
V
V
VCCOFF
Minimum Operating Voltage
L4990
L4990A
9
7
10
7.6
11
8.2
V
v
Voltage After Turn-on Hysteresis
L4990
L4990A
5.5
0.5
6
0.8
100
270
Vhys
V
v
µA
IS
Start Up Current
Before Turn-on at:
VCC = VCCON - 0.5V
Iop
Operating Current
CT = 1nF, R T = 4.42kΩ, C O =1nF
12
18
mA
Iq
Quiescent Current
(After turn on), Co =0nF
C T = 1nF, RT = 4.42kΩ,
7.0
10
mA
ISH
Shutdown Current
100
270
450
VZ
Zener Voltage
21
25
30
µA
V
I8 = 20mA
450
SYNCHRONIZATION SECTION
Master Operation
V1
Clock Amplitude
ISOURCE = 0.8mA
I1
Clock Source Current
Vclock = 3.5V
V1
Sync Pulse
Low Level
I1
Sync Pulse Current
4
V
7
mA
Slave Operation
1
V
High Level
3.5
V
VSYNC = 3.5V
0.8
mA
OVER CURRENT PROTECTION
Vt
Fault Threshold Voltage
1.1
1.2
1.3
V
2.4
2.5
2.6
V
DISABLE SECTION
Shutdown threshold
FUNCTIONAL DESCRIPTION
The I.C. contains a standard PWM current mode
control section with improved performance with
respect to the UC384X family.
Enhanced features include start-up bias current
reduced to < 270µA (typ), improved E/A performance (4MHz B/W, 1.3mA Source Current, highslew rate) accurate 1MHz oscillator, and also reduced propagation delays in the critical path from
Current Sense to Output.
4/24
ADDITIONAL FEATURES
Soft Start (SS)
An external capacitor is charged by an internal
constant current source (20µA) to generate a SS
signal which clamps the E/A output
The SS pin doubles as a Fault Reset Delay function as described below.
Current Limit / Reset Delay
An internal high-speed current limit comparator
L4990 - L4990A
referenced to 1.2V detects primary over-current
conditions. On detection of an overcurrent fault
the output is immediately shutdown and the fault
is also latched. A Fault Reset Delay is implemented by discharging the external Soft Start
(SS) timing capacitor before resetting the fault
latch and initiating a softstart cycle.
In case of a continuous fault condition the SS capacitor is charged to 5V before being discharged
again, to ensure that the fault frequency does not
exceed the programmed soft start frequency.
Duty Cycle Limit
A simple connection between the DC-LIM and the
available Vref activates an internal T- FlipFlop limiting the DC to about 50%. If this pin is not connected or grounded, the limit of the duty cycle is
extended to about 100%
Duty Cycle Control
Duty Cycle DC is externally programmed by setting a voltage between 1V (0% DC) and 3V
(100% DC) at the DC pin. The programmed voltage is compared with the oscillator CT capacitor
charging waveform to determine the maximum
ON-time in each period. This function gives a fine
control of DC.
If this pin is floating the maximum duty cycle depends on DC-LIM status.
parallel or to TV/monitor sync signal).
In TV/monitor applications the timing components
RT, CT are set for a frequency lower than the
minimum TV sync frequency. When the TV circuit
has powered-up it takes over and the system frequency is that of the SYNC. Duty Cycle is controllable using the DC function.
In parallel operation of several IC’s no Master/Slave designation is required as the higher frequency IC is automatically the master. Controllers
to be synchronized have their SYNC pins tied together and each SYNC pin operates as a bidirectional circuit. The first IC to drive its SYNC pin is
the master and it initiates a discharge of the CT
timing capacitor of every controller. The Sync input signal is edge-triggered and sets an internal
”sync latch” which ensures full discharge of CT.
Disable Function
The DIS pin performs a logic level latched-shutdown function. When pulled above 2.5V it shuts
down the complete IC with a standby current of
<270µA (typ).
To reset the IC the VCC pin must be pulled-down
below the lower UVLO threshold (10V).
Synchronization
A SYNC pin eases Synchronization of the IC to
the external world ( e.g. another IC working in
Leading Edge Blanking (LEB)
An LEB interval of 100ns has been incorporated
into the IC to blank out the current sense signal
during the first 100ns from switch turn-on.
This provides noise immunity to turn-on spikes
and reduces external RC filtering requirements on
the current-sense signal.
Figure 1. Quiescent current vs. input voltage.
(X = 7.6V and Y = 8.4V for L4990A)
Figure 2. Quiescent current vs. input voltage
(after disable).
Iq [m A ]
Iq [uA]
30
V1 4 = 0 , O SC= d isa bled
20
T j = 25° C
300
8
270
6
1
240
V14 = Vref
0 .8
T j = 25°C
0 .6
210
0 .4
0 .2
Y
X
8
0
0
4
8
12
V c c [V]
16
20
24
10
12
14
16
Vcc
18
20
22
24
[V ]
5/24
L4990 - L4990A
Figure 3. Quiescent current vs. input voltage.
Iq [m A ]
9.0
Figure 4. Quiescent current vs. input voltage
and switching frequency.
I q [mA ]
36
V 14 = 0, V5 = Vref
Rt = 4.5Kohm,Tj = 25°C
C o = 1nF, Tj = 25°C
30
8.5
D C = 0%
1M h z
24
5 0 0K h z
3 0 0K h z
8.0
1M Hz
18
1 0 0 Kh z
500K Hz
12
7.5
300K Hz
100KHz
6
7.0
8
10
12
14
16
18
V cc [V ]
20
22
24
0
8
10
12
14
16
V c c [V ]
18
20
22
Figure 5. Quiescent current vs. input voltage
and switching frequency.
Figure 6. Reference voltage vs. load current.
Iq [mA]
36
Vref [V]
5.1
Co = 1nF, Tj = 25°C
30
DC = 100%
Vcc=15V
5.05
24
1M H z
18
50 0KH z
Tj = 25°C
5
3 00KH z
12
4.95
10 0KH z
6
4.9
0
0
8
10
12
14
16
Vcc [V]
18
20
5
10
15
20
25
Iref [mA]
22
Figure 7. Vref vs. junction temperature.
Figure 8. Vref vs. junction temperature.
Vref [V])
5.1
Vref [V]
5.1
Vcc = 15V
Vcc = 15V
5.05
5.05
Iref= 20mA
Iref = 1mA
5
5
4.95
4.95
4.9
-50
6/24
-25
0
25
50
Tj (°C)
75
100
125
150
4.9
-50
-25
0
25
50
Tj (°C)
75
100
125
150
L4990 - L4990A
Figure 9. Vref SVRR vs. switching frequency.
Figure 10. Output saturation.
SVRR (dB)
V sat = V10 [V]
16
Vcc = 15V
Vcc=15V
120
14
Tj = 25°C
Vp-p=1V
12
80
10
40
8
6
0
1
10
100
1000
fsw (Hz)
10000
Figure 11. Output saturation.
0
0.2
Ipin10 [mA]
2.5
50
1
1.2
Vcc < Vccon
beforeturn-on
40
Vcc = 15V
Tj = 25°C
1.5
30
1
20
0.5
10
0
0.6
0.8
Isourc e [A]
Figure 12. UVLO Saturation
Vsat = V10 [V ]
2
0.4
0
0.2
0.4
0.6
0.8
1
1.2
0
0
200
400
Is ink [A]
Figure13. Timingresistorvs.switchingfrequency.
Figure 14. Switching frequency vs. temperature.
320
Vcc =15V, V15 =0V
2000
1000
500
Rt= 4.5Kohm, Ct = 1nF
Tj= 25°C
310
100pF
200
100
50
10
1,000 1,200 1,400
fsw (KHz)
fsw(KHz)
5000
20
600 800
Vpin10 [mV]
Vcc = 15V, V15=Vref
300
220pF
470pF
290
5.6nF
10
1nF
2.2nF
20
Rt (kohm)
30
40
280
-50
-25
0
25
50
75
100
125
150
Tj (°C)
7/24
L4990 - L4990A
Figure 15. Switching frequency vs. temperature.
Figure 16. Dead time vs Ct.
fsw (KHz)
320
Dead time [ns]
1,500
Rt= 4.5Kohm, Ct = 1nF
310
Rt =4.5Kohm
V15 = 0V
Vcc = 15V, V15= 0
1,200
300
900
V15 = Vref
600
290
300
280
-50
-25
0
25
50
75
100
125
150
2
Tj (°C)
Figure 17. Maximum Duty Cycle vs Vpin3.
4
6
8
Timing capacitor Ct [nF]
10
Figure18.Delayto outputvs junctiontemperature.
Delay to output (ns)
DC Control Voltage V pin3 [V]
3.5
130
V15 = 0V
V15 = Vr ef
120
3
110
2.5
100
2
90
Rt = 4.5Kohm ,
PIN10 = OPEN
1V pulse
on PIN13
80
Ct = 1nF
1.5
70
1
0
10
20
30
40 50 60 70
Duty C y cle [% ]
80
90 100
Phase
140
150
120
100
100
80
50
60
0
40
20
0.01
8/24
0.1
1
10
100
f (KHz)
1000
-25
0
25
50
Tj (°C)
Figure 19. E/A frequency response.
G [dB]
60
-50
10000 100000
75
100
125
150
L4990 - L4990A
work in parallel no master-slave designation is
needed because the fastest one becomes automatically the master.
During the ramp-up of the oscillator the pin is
pulled low by a 600µA generator. During the
ramp-down, that is when the pulse is released,
the 600µA pull-down is disconnected. The pin becomes a generator whose source capability is
typically 7mA (with a voltage still higher than
3.5V).
In fig. 20, some practical examples of synchronizing the L4990 are given.
APPLICATION INFORMATION
Detailed Pin Functions Description
Pin 1. SYNC (In/Out Synchronization). This function allows the IC’s oscillator either to synchronize
other controllers (master) or to be synchronized to
an external frequency (slave).
As a master, the pin delivers positive pulses during the ramp-down of the oscillator (see pin 2). In
slave operation the circuit is edge triggered. Refer
to fig. 21 to see how it works. When several IC
Figure 20. Synchronizing the L4990.
RT
SYNC
SYNC
1
L4990
VREF
1
4
VREF
2
L4981A
(MASTER)
16
L4990
2
RT
RCT
17
SYNC
1
18
4
2
RCT
VREF
RCT
RT
2 L4990 1
(MASTER)
L4981A
(SLAVE)
SYNC
SYNC
16
17
18
RCT
ROSC
CT
4
L4990
(SLAVE)
COSC
CT
(a)
(b)
Pin 2. RCT (Oscillator). A resistor (RT) and a capacitor (CT), connected as shown in fig. 21 set the
operating frequency fosc of the oscillator.
CT is charged through RT until its voltage reaches
ROSC
CT
COSC
(c)
D97IN494A
3V, then is quickly internally discharged. As the
voltage has dropped to 1V it starts being charged
again
Figure 21. Oscillator and synchronization internal schematic.
SYNC
VREF
1
4
R1
D
CLAMP
RT
R
R3
RCT
600µA
R2
+
2
Q
CLK
D1
CT
50Ω
D97IN500B
9/24
L4990 - L4990A
The frequency can be established with the aid of
fig. 13 diagrams or considering the approximate
relationship:
fosc ≅
1
CT ⋅ (0.693 ⋅ RT + KT)
Figure 22. Duty cycle control.
(1)
VREF
where KT is defined as:
R1
 90, V15 = VREF
(2)
KT = 
160 V15 = GND/OPEN
and is linked to the duration of the falling edge of
the sawtooth:
Td ≅ 30 ⋅ 10-9 + KT ⋅ CT (3)
T d is also the duration of the sync pulses delivered at pin 1 and defines the upper extreme of
the duty cycle range, Dx (see pin 15 for Dx definition and calculation).
In case V15 is connected to VREF, however, the
switching frequency of the system will be as
high as half fosc .
If the IC is to be synchronized to an external oscillator, RT and CT should be selected for a fosc
lower than the master frequency in any condition
(typically, 10-20% ), depending on the tolerance
of RT and CT itself.
Pin 3. DC (Duty Cycle Control). By biasing this
pin with a voltage between 1 and 3 V it is possible
to set the maximum duty cycle between 0 and the
upper extreme Dx (see pin 15).
If Dmax is the desired maximum duty cycle, the
voltage V3 to be applied to pin 3 is:
V3 = 5 - 2(2-Dmax) (4)
Dmax is determined by internal comparison between V3 and the oscillator ramp (see fig. 22),
thus in case the device is synchronized to an external frequency fext (and therefore the oscillator
amplitude is reduced), (4) changes into:

V3 = 5 − 4 ⋅ exp  −

Dmax 
(5)
RT ⋅ CT ⋅ fext 
A voltage below 1V will inhibit the driver output
stage. This could be used for a not-latched device
disable, for example in case of overvoltage protection (see application ideas).
If no limitation on the maximum duty cycle is required (i.e. DMAX = DX), the pin has to be left floating. An internal pull-up holds the voltage above
3V. Should the pin pick up noise (e.g. during ESD
tests), it can be connected to VREF through a
4.7kΩ resistor.
10/24
4
RT
DC
3
RCT
2
R2
+
TO PWM LOGIC
-
CT
D97IN501A
Pin 4. VREF (Reference Voltage). An internal
generator furnishes an accurate voltage reference
(5V±1.5%) that can be used to supply an external
circuit (consider some ten mA).
A small film capacitor (1 µF typ.), connected between this pin and SGND, is recommended to
preventswitching noise from affecting the reference.
Before device turn-on, this pin has a sink current capability of 0.5mA.
Pin 5. VFB (Error Amplifier Inverting Input). The
feedback signal is applied to this pin and is compared to the E/A internal reference (2.5V). The
E/A output generates the control voltage which
fixes the duty cycle.
The E/A features high gain-bandwidth product,
which allows to broaden the bandwidth of the
overall control loop, high slew-rate and current
capability, which improves its large signal behavior. Usually the compensation network, which stabilizes the overall control loop, is connected between this pin and COMP (pin 6).
Pin 6. COMP (Error Amplifier Output). Usually,
this pin is used for frequency compensation and
the relevant network is connected between this
pin and VFB (pin 5). Compensation networks towards ground are not possible since the L4990
E/A is a voltage mode amplifier (low output impedance). See application ideas for some example of compensation techniques.
Pin 7. SS (Soft-Start). At device start-up, a capacitor (Css) connected between this pin and
SGND (pin 12) is charged by an internal current
generator, ISSC, up to about 7V. During this
ramp, the E/A output is clamped by the voltage
across Css itself and allowed to rise linearly, starting from zero, up to the steady-state value imposed by the control loop. The maximum time interval during which the E/A is clamped, referred to
as soft-start time, is approximately:
L4990 - L4990A
Tss ≅
3 ⋅ Rsense ⋅ IQpk
⋅ Css
ISSC
(6)
where Rsense is the current sense resistor (see pin
13) and IQpk is the switch peak current (flowing
through Rsense), which depends on the output
load. Usually, CSS is selected for a TSS in the order of milliseconds.
Figure 23. Regulation characteristic and related quantities
VOUT
IQpk
A
D.C.M.
C.C.M.
1-2 ·IQpk
IQpk(max)
B
C
TON
D
T ON(min)
D97IN495
ISHORT IOUT(max)
IOUT
As mentioned before, the soft-start intervenes
also in case of severe overload or short circuit on
the output. Referring to fig. 23, pulse-by-pulse
current limitation is somehow effective as long as
the ON-time of the power switch can be reduced
(from A to B). After the minimum ON-time is
reached (from B onwards) the current is out of
control.
To prevent this risk, a comparator trips an overcurrent handling procedure, named ’hiccup’ mode
operation, when a voltage above 1.2V (point C) is
detected on current sense input (ISEN, pin 13).
Basically, the IC is turned off and then soft-started
as long as the fault condition is detected. As a result, the operating point is moved abruptly to D,
creating a foldback effect. Fig. 24 illustrates the
operation.
The oscillation frequency appearing on the softstart capacitor in case of permanent fault, referred
to as ’hiccup” period, is approximately given by:
 1 + 1 ⋅
 Css (7)
ISSC ISSD 
Thic ≅ 4.5 ⋅ 
Since the system tries restarting each hiccup cycle, there is not any latchoff risk.
Figure 24. Hiccup mode operation.
IOUT
SHORT
ISEN
FAULT
SS
5V
7V
0.5V
Thic
D97IN496
time
11/24
L4990 - L4990A
Figure25.Turn-on and turn-offspeeds adjustment
Rg’
VCC
9
(V)
17
13
13V
10
DRIVE &
CONTROL
OUT
L4990
D97IN497A
Rg(ON)=Rg+Rg’
Rg(OFF)=Rg
VC
8
Rg
11
PGND
”Hiccup” keeps the system in control in case of
short circuits but does not eliminate power components overstress during pulse-by-pulse limitation (from A to C). Other external protection circuits are needed if a better control of overloads is
required.
Pin 8. VCC (Controller Supply). This pin supplies
the signal part of the IC. The device is enabled as
VCC voltage exceeds the start threshold and
works as long as the voltage is above the UVLO
threshold. Otherwise the device is shut down and
the current consumption is extremely low.
An internal Zener limits the voltage on VCC to
25V. Below this value the IC current consumption
is low but increases considerably if this limit is exceeded.
A small film capacitor between this pin and SGND
(pin 12), placed as close as possible to the IC, is
recommended to filter high frequency noise.
Pin 9. VC (Supply of the Power Stage). It supplies the driver of the external switch and therefore absorbs a pulsed current. Thus it is recommended to place a buffer capacitor (towards
PGND, pin 11, as close as possible to the IC)
able to sustain these current pulses and in order
to avoid them inducing disturbances.
This pin can be connected to the buffer capacitor
directly or through a resistor, as shown in fig. 25,
to control separately the turn-on and turn-off
speed of the external switch, typically a PowerMOS. At turn-on the gate resistance is Rg + Rg’
and turn-off is Rg only.
Pin 10. OUT (Driver Output). This pin is the output of the driver stage of the external power
switch. Usually, this will be a PowerMOS, although the driver is powerful enough to drive
BJT’s (1.6A source, 2A sink, peak).
The driver is made up of a totem pole with a highside NPN Darlington and a low-side VDMOS, and
12/24
delivers a voltage internally clamped, as shown in
fig. 25. Thus it is possible to supply the driver (pin
9) with higher voltages without any problem of
damage for the gate oxide of the external MOS,
but, of course, the power dissipation on the IC will
increase.
In UVLO conditions an internal circuit (shown in
fig.26) holds the pin low in order to ensure that
the external MOS cannot be turned on accidentally. The peculiarity of this circuit is its ability to
mantain the same sink capability (typically, 20mA
@ 1V) from VCC = 0V up to the start-up threshold.
When the threshold is exceeded and the L4990
starts operating, VREFOK is pulled high (refer to
fig. 26) and the circuit is disabled.
It is then possible to omit the ”bleeder” resistor
(connected between the gate and the source of
the MOS) ordinarily used to prevent undesired
switching-on of the external MOS because of
some leakage current.
Figure 26. Pull-Down of the output in UVLO.
10
OUT
VREFOK
12
SGND
D97IN538
Pin 11. PGND (Power Ground). The current loop
during the discharge of the gate of the external
MOS is closed through this pin. This loop should
be as short as possible to reduce EMI and run
separately from signal currents return.
Pin 12. SGND (Signal Ground). This ground references the control circuitry of the IC, so all the
ground connections of the external parts related
to control functions must lead to this pin. In laying
out the PCB, care must be taken in preventing
switched high currents from flowing through the
SGND path.
Pin 13. ISEN (Current Sense). This pin is to be
connected to the ”hot” lead of the current sense
resistor Rsense (being the other one grounded), to
get a voltage ramp which is an image of the current of the switch, (IQ). When this voltage is equal
to:
L4990 - L4990A
V13pk = IQpk ⋅ Rsense =
(VCOMP − 1.4)
3
To increase the noise immunity, a ”Leading Edge
Blanking” of about 100ns is internally realized as
shown in fig. 27. Because of that, the smoothing
RC filter between this pin and Rsense could be removed or, at least, considerably reduced.
(8)
the conduction of the switch is terminated.
Figure 27. Internal LEB
2V
I
3V
+
0
CLK
ISEN
13
+
FROM E/A
PWM
COMPARATOR
TO PWM
LOGIC
-
TO FAULT
LOGIC
+
1.2V
-
OVERCURRENT
COMPARATOR
D97IN503
Pin 14. DIS (Device Disable). When the voltage
on pin 14 rises above 2.5V the IC is shut down
and it is necessary to pull VCC (IC supply voltage, pin 8) below the UVLO threshold to allow the
device to restart. When disabled, the current consumption of the IC is as low as before start-up.
The pin can be driven by an external logic signal
in case of power management, as shown in fig.
28. It is also possible to realize an overvoltage
protection, as shown in the section ” Application
Ideas”.
If used, bypass this pin to ground with a filter capacitor to avoid spurious activation due to noise
spikes. If not, it is advisable to connect the pin to
SGND, even though it might be left floating.
Figure 28. Disable (Latched)
Pin 15. DC-LIM (Maximum Duty Cycle Limit). The
upper extreme, Dx, of the duty cycle range depends on the voltage applied to this pin. Approximately,
and the output switching frequency will be halved
with respect to the oscillator one because an internal T flip-flop (see block diagram, fig. 1) is activated. Fig. 29 shows the operation.
The half duty cycle option speeds up the discharge of the timing capacitor CT (in order to get
duty cycles as close as possible to 50%) so the
oscillator frequency - with the same RT and CT will be slightly higher.
The halving of frequency can be used to reduce
losses at light load in all those systems that must
comply with requirements regarding energy consumption (e.g. monitor displays).
Dx ≅
RT
(9)
RT + 230
if DC-LIM is grounded or left floating. Instead,
connecting DC-LIM to VREF (half duty cycle option), Dx will be set approximately to:
Dx ≅
RT
(10)
2 ⋅ RT + 260
DISABLE
SIGNAL
DIS
14
+
D
-
R
Q
DISABLE
C
2.5V
UVLO
D97IN502
13/24
L4990 - L4990A
Figure 29. Half duty cycle option.
td
V15=GND
V5=V13=GND
V2
DX =
tc
tc + td
V10
tc
td
V15=VREF
V5=V13=GND
V2
DX =
tc
2 ·tc + td
V10
tc
D97IN498
DEMONSTRATION BOARD
To evaluate the device performance, a demonstration board has been realized. Despite its simplicity, it exploits most of the features of the
L4990.
The board embodies an application based on the
following specification of universal mains AC-DC
adapter:
Input voltage range: 85-270 Vac (50/60 Hz)
Output voltage: 15 V
Output current: 0.5 to 2A
Output voltage ripple : 300 mV (max.)
Load regulation: ± 5% (0.5 to 2 A load change)
Target efficiency @ Iout = 2 A: ; 80% over the
input voltage full range
Some preliminary decisions, concerning topology,
operating mode, switching frequency, maximum
duty cycle allowed and control technique, have
been made.
As for topology, at this power level and output
voltage, flyback is the most advantageous one,
mainly because of its simplicity, which means low
parts count, low cost and inherent high efficiency.
A peculiar design choice aiming at optimizing the
overall system concerns the operating mode: the
converter will work in continuous current mode at
low input voltages, when input current is greater,
and in discontinuous mode at higher input volt14/24
ages. Numerous benefits originate from that.
Compared to discontinuous current mode, continuous operation involves lower peak currents
(typ. -40%) at the same throughput power. This
implies less stress for all power components.
The transformer inductance is higher and, therefore, a smaller air gap is required for a given core:
this increases primary-to-secondary coupling and,
as a consequence, reduces leakage inductance
and improves energy transfer. Both efficiency and
load regulation will take advantage of that.
Another point in favor is a reduction of the minimum output power that the system is able to deliver keeping the output well regulated.
Few components are required in addition for
slope compensation.
Actually, continuous mode flyback suffers also
from a poor dynamic behavior during load transients because of the narrow bandwidth of the
control loop due to stability problems. However,
great dynamic performance is not required to ACDC adapters, so this problem is of no concern.
The boundary between the two operating modes
has been set at about 150 Vac (@ Iout=2A).
The selection of the switching frequency is a matter of trade-off between achieving a small transformer size and high efficiency. 200 kHz seems to
be a good compromise.
In this application, the wide input voltage range
requires a large duty cycle sweep. The higher is
the maximum duty cycle, the larger is the operat-
L4990 - L4990A
Table 1. System efficiency.
ing conditions range, in terms of input voltage and
output current, that the converter is able to cover
but, on the other hand, the higher is the peak current on the secondary side.
As to this point, the L4990 turns out to be particularly useful since it allows to set any maximum
duty cycle greater (and lower) than 50% with very
good precision. In the present case, a maximum
duty cycle of 60% for steady state operation has
been selected and an extra 5% is allowed to take
transients into account.
Since it is not requested a very tight tolerance on
the output, the feedback employs a primary side
voltage sensing technique to reduce cost and
complexity of the circuit. The same technique has
been used to protect against output overvoltages.
The electric schematic is shown in fig. 30. The
PCB layout is shown in figg. 31 and 32. Table 1
and 2 summarize typical system performance,
while table 3 lists the relevant bill of material,
where details are given only for critical components and/or where useful.
Warning: the NTC for inrush current limitation is
not assembled, thus use caution when connecting
the demo board to the mains directly. The use of
a variac or an isolation transformer is recommended.
Iout = 1A
Iout = 2A
Vin (Vac)
Vout (V)
Effic. %
Vou t (V)
Effic. %
85
14.93
83.7
14.53
84.3
110
14.95
82.5
14.55
84.9
220
14.95
81.4
14.57
85.2
270
14.96
76
14.59
81.6
Table 2. System performance.
Line regulation
Vin = 85 to 270 Vac
Iout = 0.5A
30mV
Load regulation
Iout = 0.5A to 2A
Vin = 85 Vac
Vin = 270 Vac
0.95V
0.90V
Maximum effic.
Vin = 190 Vac
Iout = 2A
86.2%
Output ripple
Vin = 85 to 270 Vac
Iout = 2A
Minimum load
Vin = 270 Vac
Vout < 20V
Transition Volt.
From C.C.M to D.C.M
Iout = 2A
< 200mV
150mA
160V
Figure 30. AC-DC adaptor electric schematic
C12
NTC
B1
85 to
270
Vac
T1
C1
R1
R2
R12
R20
R13
R21
R15
C8
R16
15V/2A
D1
R19
C2
D4
R17
GND
D3
C13
R14
C10
R5
R6
D2
C3
R4
R3
C7
VFB
R8
DCC
3
COMP
DIS
6
5
14
VCC
8
VC
10
9
R9
VREF
L4990
4
13
OUT
R7
ISEN
R24
Q1
R11
2
R10
RCT
C4
7
SS
C5
Q2
R22
12 15
DC-LIM
C6
11
SGND
PGND
R23
C11
C15
C14
D97IN499B
15/24
L4990 - L4990A
Table 3. Components List of the Fig. 30 AC-DC adaptor electric schematic.
Component
Resistors
Reference
Value
R1
1.6kΩ
2%, 1/8W
R2
9.1kΩ
2%, 1/8W
10Ω
5%, 1/8W
360kΩ
2%, 1/8W
R5
27kΩ
2%, 1/8W
R6
200kΩ
2%, 1/8W
R7
4.7Ω
2%, 1/8W
R8, R9
4.7kΩ
2%, 1/8W
R10
5.6kΩ
2%, 1/8W
R11
1Ω
R3, R14
R4
Capacitors
2%, 1/2W, metallic film (low inductance)
R12, R13
24kΩ
2%, 1/2W
R15
330Ω
5%, 1/8W
R16
-
Not used
R17
390Ω
5%,1W, 2 paralleled resistors (not used)
R19
100kΩ
5%, 1W
R20, R21
470kΩ
2%, 1/8W
R22
200Ω
5%, 1/8W
R23
2kΩ
2%, 1/8W
R24
1kΩ
5%, 1/8W
C1
100µF
400V, NCC-SMH or equiv.
C2
330µF
25V, NCC-LXF or equiv., 3 paralleled capacitors
C3
47µF
25V, electrolytic
C4
1µF
10V, electrolytic
C5
1nF
J precision
C6, C15
10nF
C7, C14
330pF
C8
330pF
C9
100nF
C10
220nF
C11
100pF
ceramic
C12
-
Not used
160V, polypropilene
C13
4.7nF
630V
Transformer
T1
380µH
Core: EFD25, Philips, 3F3 ferrite (or equivalent)
Primary: 46 T, litz wire 20 x 0.1, interleaved assembly
Secondary: 6 T, 4 paralleled litz wire 20 x 0.1
Auxiliary: 7 T (evenly spaced), ∅ 0.2 mm GAP ~ 0.7mm
Transistors
Q1
STP5NA80
Q2
2N2222
ST (or equivalent)
B1
DF04M
GI (or equivalent)
D1
STPS20100CT
Diodes
D2, D3
D4
16/24
Description
ST, TO220 package
ST, Shottky, TO220 package
1N4148
ST (or equivalent)
BYT11-600
ST, F126 package
Fuse
Fuse
T2A250V
NTC
NTC
-
ELU (or equivalent)
Not used (see warning)
L4990 - L4990A
Figure 31. AC-DC adaptor PCB layout (1.25 :1 scale) - Component Side.
Figure 32. AC-DC adaptor PCB layout (1.25 :1 scale) - Back Side.
17/24
L4990 - L4990A
and the inductance of the wiring.
4) Magnetic field radiation (and stray inductance)
can be reduced by keeping all traces carrying
switched currents as short as possible.
5) In general, traces carrying signal currents
should run far from traces carrying pulsed currents or with quickly swinging voltages. From
this viewpoint, particular care should be taken
of the high impedance points (current sense input, feedback input, ...). It could be a good idea
to route signal traces on one PCB side and
power traces on the other side.
6) Provide adequate filtering of some crucial
points of the circuit, such as voltage references, IC’s supply pins, etc.
Layout hints. Generally speaking a proper circuitboard layout is vital for correct operation but is
not an easy task. Careful component placing, correct traces routing, appropriate traces widths and,
in case of high voltages, compliance with isolation
distances are the major issues. The L4990 eases
this task by putting two pins at disposal for separate current returns of bias (SGND) and switch
drive currents (PGND) The matter is complex and
only few important points will be here reminded.
1) All current returns (signal ground, power
ground, shielding, etc.) should be routed separately and should be connected only at a single
ground point.
2) Noise coupling can be reduced by minimizing
the area circumscribed by current loops. This
applies particularly to loops where high pulsed
currents flow.
3) For high current paths, the traces should be
doubled on the other side of the PCB whenever
possible: this will reduce both the resistance
APPLICATION IDEAS
Here follows a series of ideas/suggestionsaimed at
either improving performance or solving common
application problems of L4990-basedsupplies.
Figure 33. Isolated MOSFET Drive & Current Transformer Sensing in 2-switch Topologies.
VIN
ISOLATION
BOUNDARY
VC
9
10
OUT
L4990
13
12
PGND
ISEN
11
SGND
D97IN504
Figure 34. Low consumption start-up
VIN
2.2MΩ
33KΩ
STD1NB50-1
T
VCC
VREF
22V
47KΩ
4
8
L4990
12
D97IN505A
18/24
11
SELF-SUPPLY
WINDING
L4990 - L4990A
Figure 35. Bipolar Transistor Drive
VIN
VCC
VC
9
8
10
13
L4990
OUT
ISEN
11
PGND
D97IN506
Figure 36. Typical E/A compensation networks.
From VO
+
2.5V
1.3mA
Ri
VFB
Rd
Cf
2R
+
5
-
EA
R
Rf
COMP
6
12
SGND
Error Amp compensation circuit for stabilizing any current-mode topology except
for boost and flyback converters operating with continuous inductor current.
From VO
+
2.5V
1.3mA
RP
Ri
CP
Rd
VFB
Cf
5
Rf
COMP
6
2R
+
-
EA
R
12
SGND
D97IN507
Error Amp compensation circuit for stabilizing current-mode boost and flyback
topologies operating with continuous inductor current.
19/24
L4990 - L4990A
Figure 37. Feedback with optocoupler
VOUT
COMP
6
L4990
5
TL431
VFB
D97IN508
Figure 38. Slope compensation techniques
V REF
VREF
4
RT
RT
RCT
I
RSLOPE
2
CT
13
10
OUT
R
RCT
R
2
CSLOPE
CT
L4990
ISEN
4
I
RSLOPE
L4990
ISEN
12
RSENSE
SGND
OPTIONAL
13
RSENSE
L4990
12
12
SGND
13
ISEN
RSLOPE
RSENSE
SGND
OPTIONAL
OPTIONAL
D97IN509A
Figure 39. Protection against overvoltage/feedbackdisconnection (latched)
RSTART
RSTART
VCC
DIS
8
DIS
L4990
14
12
11
SGND
2.2K
PGND
D97IN510
20/24
VCC
VZ
8
L4990
14
12
11
SGND
PGND
D98IN904
L4990 - L4990A
Figure 40. Protection against overvoltage/feedback disconnection (not
latched)
Figure 41. Device shutdown on overcurrent
RSTART
Ipk max ≅
VREF
4
R1
VREF
DC
•
1-
R2
R1
Ipk
14
L4990
8
R2
L4990
3
I
DIS
VCC
4
2.5
R SENSE
11
12
ISEN
13
RSENSE
SGND
PGND
11
12
OPTIONAL
D97IN512A
D97IN511A
Figure 42. Constant power in pulse-by-pulse current limitation (flyback discontinuous)
VIN
80 ÷ 400VDC
Lp
RFF
6
OUT
RFF = 5·10
10
L4990
11
PGND
12
13
R·Lp
RSENSE
ISEN
R
RSENSE
SGND
D97IN513
Figure 43. Voltage mode operation.
DC
3
10K
COMP
L4990
6
SGND
12
13
ISEN
D97IN570A
REFERENCES
[1] Efficient active Clamp for Off-line Applications using L4990 and L6380 (N.Tricomi, G. Gattavari,
C. Adragna, PCIM96 - NURBERG).
[2] 25W Off-Line Autoranging Battery Charger with L4990 (AN889)
[3] 300W Secondary Controlled Two-Switch Forward Converter with L4990 (AN890)
[4] SMPS with L4990 for Multisync Monitors (AN891)
[5] High performance VRM using L4990A, for Pentium Pro processor (AN908).
21/24
L4990 - L4990A
mm
DIM.
MIN.
a1
0.51
B
0.77
TYP.
inch
MAX.
MIN.
TYP.
MAX.
0.020
1.65
0.030
0.065
b
0.5
0.020
b1
0.25
0.010
D
20
0.787
E
8.5
0.335
e
2.54
0.100
e3
17.78
0.700
F
7.1
0.280
I
5.1
0.201
L
Z
22/24
OUTLINE AND
MECHANICAL DATA
3.3
0.130
1.27
DIP16
0.050
L4990 - L4990A
mm
DIM.
MIN.
TYP.
inch
MAX.
MIN.
TYP.
MAX.
A
2.35
2.65
0.093
0.104
A1
0.1
0.3
0.004
0.012
B
0.33
0.51
0.013
0.020
C
0.23
0.32
0.009
0.013
D
10.1
10.5
0.398
0.413
E
7.4
7.6
0.291
0.299
e
1.27
0.050
H
10
10.65
0.394
0.419
h
0.25
0.75
0.010
0.030
L
0.4
1.27
0.016
0.050
K
OUTLINE AND
MECHANICAL DATA
SO16 Wide
0° (min.)8° (max.)
L
h x 45
A
B
e
K
A1
C
H
D
16
9
E
1
8
23/24
L4990 - L4990A
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. Specification 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.
The ST logo is a registered trademark of STMicroelectronics
 1999 STMicroelectronics – Printed in Italy – All Rights Reserved
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24/24