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Voltage Regulators
AN8049SH
1.8-volt 3-channel step-up, step-down, and polarity inverting DC-DC converter control IC
Unit : mm
0.10.1
(0.5)
I Features
5.50.3 7.50.3
* Wide operating supply voltage range: 1.8 V to 14 V * High-precision reference voltage circuit SSOP024-P-0300A -- VREF pin voltage: 1% Note) The package of this product will be changed -- Error amplifier: 1.5% to lead-free type (SSOP024-P-0300D). See the * Surface mounting package for miniaturized and thinner new package dimensions section later of this power supplies * Supports control over a wide output frequency range: 20 kHz to 1 MHz datasheet. * On/off (sequence control) pins provided for each channel for easy sequence control setup * The negative supply error amplifier supports 0-volt input. Common-mode input voltage range: - 0.1 V to VCC -1.4 V This allows the number of external components to be reduced by two resistors. * Fixed duty factor: 86% However, the duty can be adjusted to anywhere from 0% to 100% with an external resistor. * Timer latch short-circuit protection circuit (charge current: 1.1 A typical) * Low input voltage malfunction prevention circuit (U.V.L.O.) (operation start voltage: 1.67 V typical) * Standby function (active-high control input, standby mode current: 1 A maximum) * Alternate package versions also available. Part No.: AN8049FHN Package: QFN024-P-0405A (Lead-free package) 0.5-mm lead pitch Width 5.20 mm 0.10 mm Depth 4.20 mm 0.10 mm Thickness 0.8 mm (max.)
I Applications
* Electronic equipment that requires a power supply system
0.650.1
0.15 +0.1 -0.05
1.50.2
The AN8049SH is a three-channel PWM DC-DC converter control IC that features low-voltage operation. This IC can form a power supply that provides two stepup outputs and one step-down or polarity inverted output with a minimal number of external components. The AN8049SH features the ability to operate from a supply voltage as low as 1.8 V, and thus can be operated from two dry-batteries.
1
24
0.5
I Overview
12
13
0.20.1
0.650.1
6.50.3
Publication date: December 2001
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1
AN8049SH
CTL1
I Block Diagram
IN-1 FB1
VREF
OSC
DT1
VCC
24
16
23
7
9
4
17
1.1 A
1.26 V (Allowance: 1%)
Error amplifier 1
20 k 1.26 V VCC 1.1 A S.C.P. comp. U.V.L.O. R Q S Latch 1.26 V
45 k
Reference voltage supply VREF
Sawtooth wave generator 0.7 V V 0.3 V On/off CC control 11 55 k PWM1
8
Off
RB1 OUT1
12
1.26 V
S.C.P. FB3
20
Error amplifier 2
DT3 CTL3
2 5
Error amplifier 3
56 k 44 k
18 IN+3 19 IN-3
0.9 V VREF
PWM3
15
27 k
1
OUT3
1.1 A 20 k 1.26 V PWM2
VCC
10 13
RB2 OUT2
20 k
1.26 V
1.1 A
VREF
45 k 1.26 V 55 k
14
27 k
21
22
GND
6
CTL2
IN-2
I Pin Descriptions
Pin No. 1 Symbol S.C.P. Description Connection for the capacitor that provides the short-circuit protection circuit time constant Channel 3 soft start setting Channel 2 soft start setting Channel 1 soft start setting Channel 3 on/off control Channel 2 on/off control Channel 1 on/off control On/off control Reference voltage output Connection for the OUT2 block output source current setting resistor Connection for the OUT1 block output source current setting resistor Pin No. 12 13 14 15 16 17 18 19 20 21 22 23 24 Symbol OUT1 OUT2 GND OUT3 VCC OSC IN+3 IN-3 FB3 IN-2 FB2 IN-1 FB1 Description OUT1 block push-pull output OUT2 block push-pull output Ground OUT3 block open-collector output Supply voltage Oscillator circuit timing resistor and capacitor connection Error amplifier 3 noninverting input Error amplifier 3 inverting input Error amplifier 3 output Error amplifier 2 inverting input Error amplifier 2 output Error amplifier 1 inverting input Error amplifier 1 output
2 3 4 5 6 7 8 9 10 11
DT3 DT2 DT1 CTL3 CTL2 CTL1 Off VREF RB2 RB1
2
SDH00012BEB
DT2
FB2
3
AN8049SH
I Absolute Maximum Ratings
Parameter Supply voltage Off pin allowable application voltage CTL pin allowable application voltage Error amplifier input pin allowable application voltage *2 Supply current OUT1 and OUT2 pin output source current OUT3 pin output current Power dissipation
*1
Symbol VCC VOFF VCTL VIN ICC ISO(OUT) IO PD Topr Tstg
Rating 14.2 14.2 VCC - 0.2 6 -50 +50 146 -30 to +85 -55 to +125
Unit V V V V mA mA
mA mW C C
Operating temperature Storage temperature
Note) 1. Do not apply external currents or voltages to any pins not specifically mentioned. For circuit currents, '+' denotes current flowing into the IC, and '-' denotes current flowing out of the IC. 2. Items other than the storage temperature, operating temperature, and power dissipation are all stipulated for an ambient temperature Ta = 25C. 3. *1: Ta = 85C. See the "Application Notes" for details on the relationship between IC power dissipation and the ambient temperature. *2: When VCC < 6 V, the following condition must hold: VIN-1 = VIN-2 = VCC - 0.2 V.
I Recommended Operating Range
Parameter Off pin application voltage OUT1 and OUT2 pin output source current OUT3 pin output current Timing resistance Timing capacitance Oscillator frequency Short-circuit protection time-constant setting capacitance Output current setting resistance Symbol VOFF ISO(OUT) IO RT CT fOUT CSCP RB Range 0 to 14 -40 to -1 40 (max.) 3 to 33 100 to 10 000 20 to 1 000 1 000 (min.) 750 to 15 000 k pF kHz pF Unit V mA
I Electrical Characteristics at VCC = 2.4 V, CREF = 0.1 F, Ta = 25C
Parameter Reference voltage block Reference voltage Line regulation with input fluctuation Load regulation U.V.L.O. block Circuit operation start voltage VUON
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Symbol
Conditions IREF = - 0.1 mA VCC = 1.8 V to 14 V IREF = - 0.1 mA to -1 mA
Min
Typ
Max
Unit
VREF Line Load
1.247 -20
1.26 2 -3
1.273 20
V mV mV
1.59
1.67
1.75
V 3
AN8049SH
I Electrical Characteristics at VCC = 2.4 V, CREF = 0.1 F, Ta = 25C (continued)
Parameter Error amplifier 1 block Input threshold voltage 1 Input bias current 1 High-level output voltage 1 Low-level output voltage 1 Output source current 1 Output sink current 1 Error amplifier 2 block Input threshold voltage 2 Input bias current 2 High-level output voltage 2 Low-level output voltage 2 Output source current 2 Output sink current 2 Error amplifier 3 block Input offset voltage Common-mode input voltage range Input bias current 3 High-level output voltage 3 Low-level output voltage 3 Output source current 3 Output sink current 3 Oscillator block Oscillator frequency Output 1 block Output duty factor 1 High-level output voltage 1 Low-level output voltage 1 Output source current 1 Output sink current 3 Pull-down resistor 1 Output 2 block Output duty factor 2 High-level output voltage 2 Low-level output voltage 2 Output source current 2 Output sink current 2 4 Du2 VOH2 VOL2 RT = 7.5 k, CT = 680 pF IO = -10 mA, RB = 1 k IO = 10 mA, RB = 1 k VO = 0.7 V, RB = 1 k
SDH00012BEB
Symbol
Conditions
Min
Typ
Max
Unit
VTH1 IB1 VEH1 VEL1 ISO(FB)1 ISI(FB)1 VTH2 IB2 VEH2 VEL2 ISO(FB)2 ISI(FB)2
1.241 1.0 -38 0.5
1.26 0.1 1.2 -31 1.26 0.1 1.2 -31 - 0.3 1.2 -31 190
1.279 0.2 1.4 0.2 -24 1.279 0.2 1.4 0.2 -24
V A V V A mA
1.241 1.0 -38 0.5 -6 - 0.1 - 0.6 1.0 -38 0.5 RT = 7.5 k, CT = 680 pF RT = 7.5 k, CT = 680 pF IO = -10 mA, RB = 1 k IO = 10 mA, RB = 1 k VO = 0.7 V, RB = 1 k
V A V V A mA
VIO VICR IB3 VEH3 VEL3 ISO(FB)3 ISI(FB)3 fOUT
6 VCC - 1.4 1.4 0.2 -24 210
mV V A V V A mA
170
kHz
Du1 VOH1 VOL1 ISI(OUT)1 RO1
80 VCC -1 -34 40 17
86 -29 27
92 0.2 -24 37
% V V mA mA k
ISO(OUT)1 VO = 0.7 V, RB = 1 k
80 VCC -1 -34 40
86 -29
92 0.2 -24
% V V mA mA
ISO(OUT)2 VO = 0.7 V, RB = 1 k ISI(OUT)2
AN8049SH
I Electrical Characteristics at VCC = 2.4 V, CREF = 0.1 F, Ta = 25C (continued)
Parameter Output 2 block (continued) Pull-down resistor 2 Output 3 block Output duty factor 3 Output saturation voltage Output leakage current Short-circuit protection circuit block Input standby voltage Input threshold voltage Input latch voltage Charge current On/off control block Input threshold voltage CTL block Input threshold voltage Charge current Whole Device Average consumption current Standby mode current * Design reference data
Note: The characteristics listed below are reference values related to the IC design and are not guaranteed.
Symbol
Conditions
Min
Typ
Max
Unit
RO2 RT = 7.5 k, CT = 680 pF IO = 40 mA V13 = 14 V
17
27
37
k
Du3 VO(SAT) IOLE
80 0.8
86 0.9
92 0.5 1
% V A
VSTBY VTHPC VIN ICHG VSCP = 0 V
0.1 1.0 0.1
V V V A
-1.43
-1.1 - 0.77
VON(TH) VTHCTL ICTL ICC(OFF) ICC(SB) VCTL = 0 V RB = 9.1 k, duty = 50%
0.6
0.9
1.2
V
1.07 -1.43
1.26
1.45
V A mA A
-1.1 - 0.77 4.2 5.5 1
Parameter Reference voltage block VREF temperature characteristics Error amplifier 1 block VTH temperature characteristics Open loop gain 1 Error amplifier 2 block VTH temperature variation Open loop gain 2 Error amplifier 3 block Open loop gain 3 Oscillator block Frequency supply voltage characteristics Frequency temperature characteristics
Symbol
Conditions Ta = -30C to +85C Ta = -30C to +85C
Min
Typ
Max
Unit
VRFEdT
1
%
VTHdT1 AV1
1.5 80
% dB
VTHdT2 AV2
1.5 80
% dB
AV3 fDV fDT VCC = 1.8 V to 14 V RT = 7.5 k, CT = 680 pF Ta = -30C to +85C RT = 7.5 k, CT = 680 pF
80
dB

1 3
% %
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5
AN8049SH
I Electrical Characteristics at Ta = 25C (continued)
* Design reference data (continued)
Note: The characteristics listed below are reference values related to the IC design and are not guaranteed.
Parameter
Symbol
Conditions
Min
Typ
Max
Unit
Short-circuit protection circuit block Comparator threshold voltage On/off control block Off pin current IOFF VOFF = 5 V 38 A VTHL 1.26 V
I Terminal Equivalent Circuits
Pin No. 1 Equivalent circuit Description S.C.P.: Connection for the capacitor that sets the timer latch short-circuit protection circuit time constant. Use a capacitor with a value of 1 000 pF or higher. The charge current ICHG is 1.1 mA typical. I/O O
VCC 1.1 A 1.5 k
Latch S Q 1.26 V R Output shutoff
1
2 DT3: Sets the channel 3 soft start time. Set the time by connecting a capacitor between this pin and ground. (See the "Application Notes, [7]" section.) Note that although the channel 3 maximum on duty is set internally to 86%, the maximum on duty can be adjusted by connecting resistors between this pin and ground, and between this pin and the VREF pin. (See the "Application Notes, [6]" section.) DT2: Sets the channel 2 soft start time. Set the time by connecting a capacitor between this pin and ground. (See the "Application Notes, [7]" section.) Note that although the channel 2 maximum on duty is set internally to 86%, the maximum on duty can be adjusted by connecting resistors between this pin and ground, and between this pin and the VREF pin. (See the "Application Notes, [6]" section.) I
9 20 17 44 k 46 k PWM3
2
3
I
9 22 17 45 k 55 k PWM2
3
6
SDH00012BEB
AN8049SH
I Terminal Equivalent Circuits (continued)
Pin No. 4 Equivalent circuit Description DT1: Sets the channel 1 soft start time. Set the time by connecting a capacitor between this pin and ground. (See the "Application Notes, [7]" section.) Note that although the channel 1 maximum on duty is set internally to 86%, the maximum on duty can be adjusted by connecting resistors between this pin and ground, and between this pin and the VREF pin. (See the "Application Notes, [6]" section.) CTL3: Controls the on/off state of channel 3. A delay can be provided in the power supply turn-on start time by connecting a capacitor between this pin and ground. (See the "Application Notes, [9]" section.) tDLY3 = 1.26 (V) x CCTL3 (F)/1.1 (A) (s) This pin can also be used to control the on/off state with an external signal. In that case, the allowable input voltage range is from 0 V to VCC. Note that during U.V.L.O. and timer latch operation, this pin is connected to ground through a 20 k resistor. CTL2: Controls the on/off state of channel 2. A delay can be provided in the power supply turn-on start time by connecting a capacitor between this pin and ground. (See the "Application Notes, [9]" section.) tDLY2 = 1.26 (V) x CCTL2 (F)/1.1 (A) (s) This pin can also be used to control the on/off state with an external signal. In that case, the allowable input voltage range is from 0 V to VCC. Note that during U.V.L.O. and timer latch operation, this pin is connected to ground through a 20 k resistor. I/O I
9 24 17 45 k 55 k PWM1
4
5
I
VCC 1.1 A
20 k
High Channel 3 1.26 V output operation
5
6
I
VCC 1.1 A
20 k
High Channel 2 1.26 V output operation
6
SDH00012BEB
7
AN8049SH
I Terminal Equivalent Circuits (continued)
Pin No. 7 Equivalent circuit Description CTL1: Controls the on/off state of channel 1. A delay can be provided in the power supply turn-on start time by connecting a capacitor between this pin and ground. (See the "Application Notes, [9]" section.) tDLY3 = 1.26 (V) x CCTL1 (F)/1.1 (A) (s) This pin can also be used to control the on/off state with an external signal. In that case, the allowable input voltage range is from 0 V to VCC. Note that during U.V.L.O. and timer latch operation, this pin is connected to ground through a 20 k resistor. Off: Controls the on/off state. When the input is high: normal operation (VOFF > 1.2 V) When the input is low: standby mode (VOFF < 0.6 V) In standby mode, the total current consumption is held to under 1 A. VREF: Outputs the internal reference voltage. The reference voltage is 1.26 V (allowance: 1%) when VCC is 2.4 V and IREF is - 0.1 mA. Insert a capacitor of at least 0.1 F between VREF and ground for phase compensation. RB2: Connection for a resistor that sets the channel 2 output current. Use a resistor in the range 750 to 15 k. I/O I
VCC 1.1 A
20 k
High Channel 1 1.26 V output operation
7
8
I
8
100 k
Start and stop of internal circuits.
9
VCC
O
9
10
16
I
ISO(OUT)2 13 200 10
11 16
ISI(OUT)2
30 k
ISO(OUT)1 12 200 11 ISI(OUT)1 30 k
RB1: Connection for a resistor that sets the channel 1 output current. Use a resistor in the range 750 to 15 k.
I
8
SDH00012BEB
AN8049SH
I Terminal Equivalent Circuits (continued)
Pin No. 12 See pin 11. Equivalent circuit Description OUT1: Push-pull output. The absolute maximum rating for the output source current is -50 mA. The output source current is set by the external resistor connected to the RB1 pin. OUT2: Push-pull output. The absolute maximum rating for the output source current is -50 mA. The output source current is set by the external resistor connected to the RB2 pin. GND: Ground 14 15 OUT3: Open-collector output. The absolute maximum rating for the output current is +50 mA. I/O O
13
See pin 10.
O
14
16 15
O
16
16
VCC: Power supply. Provide the operating supply voltage in the range 1.8 V to 14 V. OSC: Connection for the capacitor and resistor that determine the oscillator frequency. Use a capacitor in the range 100 pF to 1 000 pF and a resistor in the range 3 k to 33 k. Use an oscillator frequency in the range 20 kHz to 1 MHz. IN+3: Noninverting input to the error amplifier 3. IN-3: Inverting input to the error amplifier 3. FB3: Output from the error amplifier 3. This circuit can provide a source current of -31 A or a sink current of 0.5 mA (minimum).
17
VCC Latch S Q 0.2 V R 17
O
18
16
I
19
19 100
9
100
18
I
20
O
31 A OSC PWM3 18 19 0.5 mA 20
SDH00012BEB
9
AN8049SH
I Terminal Equivalent Circuits (continued)
Pin No. 21 Equivalent circuit Description IN-2: Inverting input to the error amplifier 2. I/O I
16
21
1.5 k 1.26 V
22
16 21 1.19 V 31 A OSC 0.5 mA min. 22 PWM2
FB2: Output from the error amplifier 2. This circuit can provide a source current of -31 A or a sink current of 0.5 mA (minimum).
O
23
16
IN-1: Inverting input to the error amplifier 1.
I
23
1.5 k 1.26 V
24
16 23 1.19 V 31 A OSC 0.5 mA min. 24 PWM2
FB1: Output from the error amplifier 1. This circuit can provide a source current of -31 A or a sink current of 0.5 mA (minimum).
O
10
SDH00012BEB
AN8049SH
I Usage Notes
[1] Allowable power dissipation 1. Since the power dissipation (P) in this IC increases proportionally with the supply voltage, applications must be careful to operate so that the loss does not exceed the allowable power dissipation, PD, for the package. See the PD Ta curve. Reference formula: P = (VCC -VBEQ1) x ISO(OUT)1 x Du1 + (VCC - VBEQ2) x ISO(OUT)2 x Du2 + VO(SAT)3 x IOUT3 x Du3 + VCC x ICC < PD VBEQ1 : The voltage between the base and emitter of the channel 1 npn transistor ISO(OUT)1 : The OUT1 pin output source current (This is set by the resistor connected to the RB1 pin. When RB is 1 k, ISO(OUT)1 will be 34 mA, maximum.) Du1 : The output 1 on-duty VBEQ2 : The voltage between the base and emitter of the channel 2 npn transistor ISO(OUT)2 : The OUT2 pin output source current (This is set by the resistor connected to the RB2 pin. When RB is 1 k, ISO(OUT)2 will be 34 mA, maximum.) Du2 : The output 2 on-duty VO(SAT)3 : The OUT3 pin saturation voltage (0.5 V maximum when IOUT3 is 40 mA.) IOUT3 : The OUT3 pin current (This will be {VCC - VBEQ3 - VO(SAT)3}/RO3 .) Du3 : The output 3 on-duty ICC : The VCC pin current 2. If the IC is shorted to ground, shorted to VCC, or inserted incorrectly, either the device itself or peripheral components will be destroyed. [2] Allowable VCC ripple VCC ripple due to the switching transistor being turned on and off can cause this IC's U.V.L.O. circuit, which is biased by VCC, to operate incorrectly, and can cause the S.C.P. capacitor charging operation to fail to start when the output is shorted. The figure shows the allowable range for VCC ripple. Applications should reduce VCC ripple either by inserting a ripple filter in the VCC line or by inserting a capacitor between the IC GND and VCC pins and locating that capacitor as close to the IC as possible. Note that the allowable range shown here is the result of testing the IC independently, and that the allowable range may differ depending on the actual system of the power supply circuit. Also note that this allowable range is a design target, and is not guaranteed by testing of all samples. Allowable VCC ripple
10M
Ripple frequency (Hz)
Allowable range when VCC is 3 V. 1M
100k
Allowable range when VCC is 10 V. 10k 0 1 2 3 4 5 6 7 8
VCC ripple voltage VCC(AC) (V[p-p])
SDH00012BEB
11
AN8049SH
I Usage Notes (continued)
[3] Notes on MOS drive Since the AN8049SH channel 1 and 2 output circuits were designed to drive bipolar transistors, the following points require care if this device is used to drive n-channel MOS transistors directly. 1. Use an n-channel MOS transistor with a low input capacitance. The AN8049SH is designed to drive bipolar transistors, and adopts a circuit structure that can provide a constant-current (50 mA maximum) output source current. Furthermore, it has a sink current capacity of 80 mA maximum. This means that designs must be concerned about increased loss due to longer rise- and fall-times. If a problem occurs, an inverter may be inserted as shown in figure 1 to provide amplification. 2. Use an n-channel MOS transistor with a low gate-threshold voltage. Since the AN8049SH OUT1 and OUT2 pin high-level output voltage is VCC - 1.0 V (minimum), low VT MOS transistors with an adequately low on-resistance must be used. Also, if a large VGS is required, one solution is to use a transformer as shown in figure 2, and apply a voltage that is twice the input voltage to the IC's VCC pin.
VIN VOUT
OUT1/2 Figure 1. Output bootstrap circuit VIN VCC VOUT
OUT1/2 VCC 2 x VIN - VD Figure 2. Gate drive voltage bootstrap technique
I Application Notes
[1] PD Ta curves of SSOP024-P-0300A PD T a
700 658 600 Glass epoxy printed circuit board (75 x 75 x t1.6 mm3) Rth(j-a) = 152C/W PD = 658 mW(25C) Independent IC without a heat sink Rth(j-a) = 273C/W PD = 366 mW(25C)
Power dissipation PD (mW)
500
400 366 300 263 200 146 100
0 0 25 50 75 85 100 125
Ambient temperature Ta (C)
12
SDH00012BEB
AN8049SH
I Application Notes (continued)
[2] Main characteristics Timing capacitance Oscillator frequency
1M
DT1 and DT2 pin voltage Maximum on-duty
100 90 80 70 f = 190 kHz
fOUT (Hz)
Du (%)
RT = 3 k 100k RT = 7.5 k
60 50 40 30 20
f = 1 MHz
RT = 33 k 10k 10p
10
10n
1n
0 0.2
0.3
0.4
0.5
0.6
0.7
0.8
CT (F)
VDT (V)
DT3 pin voltage Maximum on-duty
100 90 80 f = 190 kHz f = 1 MHz 90 95
fOSC Maximum output duty
RT = 3 k
Du1 , Du2 , Du3 (%)
70
Du3 Du1 , Du2
Du3 (%)
60 50 40 30 20 10 0 0.2 0.3 0.4 0.5 0.6 0.7 0.8
85
80
75 10k
100k
1M
VDT3 (V)
fOSC (Hz)
fOSC Maximum output duty
95 RT = 7.5 k
fOSC Maximum output duty
95 RT = 33 k
Du2
90
90
Du3 Du1
Du1 , Du2 , Du3 (%)
Du1 , Du2 , Du3 (%)
85
Du3
85
Du1 , Du2 80
80
75 10k
100k
1M
75 10k
100k
1M
fOSC (Hz)
fOSC (Hz)
SDH00012BEB
13
AN8049SH
I Application Notes (continued)
[2] Main characteristics (continued) RB ISO(OUT)
0 -10 -20 VCC = 1.8 V
RB ISI(OUT)
100 90 80 70
ISO(OUT) (mA)
ISI(OUT) (mA)
-30 2.4 V -40 -50 -60 8V
60 50 40 30 20
VCC = 14 V
8V 1.8 V, 2.4 V 1k 10k 100k
-70 -80 100
14 V
10
1k 10k 100k
0 100
RB ()
RB ()
14
SDH00012BEB
AN8049SH
I Application Notes (continued)
[3] Timing charts VCC pin voltage waveform 1.67 V Output short 1.26 V S.C.P. pin voltage waveform
VCC 1.26 V 0V CTL pin voltage waveform
FB
OSC
DT
OSC
OUT1/2 pin voltage waveform Totem pole circuit output
OUT3 pin voltage waveform Open-collector output
SDH00012BEB
15
AN8049SH
I Application Notes (continued)
[4] Function descriptions 1. Reference voltage block This circuit is composed of a band gap circuit, and outputs a 1.26 V (typical) reference voltage that is temperature compensated to a precision of 1%. This reference voltage is stabilized when the supply voltage is 1.8 V or higher. This reference voltage is used by error amplifiers 1 and 2. 2. Triangular wave generator This circuit generates a triangular wave like a VOSCH sawtooth with a peak of 0.7 V and a trough of 0.2 V 0.7 V using a capacitor CT (for the time constant) and resistor RT connected to the OSC1 pin (pin 17). The oscillator frequency can be set to an arbitrary value by selecting VOSCL appropriate values for the external capacitor CT and 0.2 V t2 resistor RT. This IC can use an oscillator frequency in t1 the range 20 kHz to 1 MHz. The triangular wave signal Discharge is provided to the noninverting input of the PWM com- Rapid charge T parator in each channel internally to the IC. Use the formulas below for rough calculation of the oscillator Figure 1. Triangular oscillator waveform frequency. 1 1 fOSC - 0.8 x (Hz) VOSCL CT x RT CT x RT x ln VOSCH Note, however, that the above formulas do not take the rapid charge time, overshoot, and undershoot into account. See the experimentally determined graph of the oscillator frequency vs. timing capacitance value provided in the main characteristics section. FB1 24 3. Error amplifier 1 This circuit is an npn-transistor input error amplifier VOUT1 that detects and amplifies the DC-DC converter output Error voltage, and inputs that signal to a PWM comparator. R1 amplifier1 The 1.26 V internal reference voltage is applied to the 23 noninverting input. Arbitrary gain and phase compensaIN-1 tion can be set up by inserting a resistor and capacitor in 1.26 V To the PWM R2 comparator input series between the FB1 pin (pin 24) and the IN-1 pin (pin 23). The output voltage VOUT1 can be set using the RR VOUT1 = 1.26 x 1 + 2 circuit shown in the figure. R
2
4. Error amplifier 2 This circuit is an npn-transistor input error amplifier that detects and amplifies the DC-DC converter output voltage and inputs that signal to a PWM comparator. The 1.26 V internal reference voltage is applied to the noninverting input. Arbitrary gain and phase compensation can be set up by inserting a resistor and capacitor in series between the FB2 pin (pin 22) and the IN-2 pin (pin 21). The output voltage VOUT2 can be set using the circuit shown in the figure.
Figure 2. Connection method of error amplifier 1 (Step-up output) FB2 22 VOUT2 R1 21 IN-2 R2 VOUT2 = 1.26 x Error amplifier2 1.26 V To the PWM comparator input R1 + R2 R2
Figure 3. Connection method of error amplifier 2 (Step-up output)
16
SDH00012BEB
AN8049SH
I Application Notes (continued)
[4] Function descriptions (continued) 5. Error amplifier 3 This circuit is an pnp-transistor input error amplifier that detects and amplifies the DC-DC converter output voltage and inputs that signal to a PWM comparator. Arbitrary gain and phase compensation can be set up by inserting a resistor and capacitor in series between the FB3 pin (pin 20) and the IN-3 pin (pin 19). The output voltage VOUT3 can be set using the circuit shown in the figure. Step-down output Inverting output
FB3 20 VREF VOUT3 R1 R3
IN+3 18
FB3 20 VREF Error amplifier3 To the PWM comparator input R1
IN+3 18
Error amplifier3 To the PWM comparator input R2 R1
19
19
R2
R4
IN-3
R2 VOUT3
IN-3
R +R R2 VOUT3 = x 3 4 x VREF R4 R1+R2
VOUT3 = -VREF x
Figure 4. Connection method of error amplifier 3
6. Timer latch short-circuit protection circuit This circuit protects the external main switching elements, flywheel diodes, choke coils, and other components against degradation or destruction if an excessive load or a short circuit of the power supply output continues for longer than a certain fixed period. The timer latch short-circuit protection circuit detects the output of the error amplifiers. If the DC-DC converter output voltage drops and an FB pin (pins 20, 22, or 24) voltage exceeds 0.9 V, the S.C.P. comparator outputs a low level and the timer circuit starts. This starts charging the external protection circuit delay time capacitor. If the error amplifier output does not return to the normal voltage range before that capacitor reaches 1.26 V, the latch circuit latches, the output drive transistors are turned off, and the dead-time is set to 100%. (See the "[5] Time constant setup for the timer latch short-circuit protection circuit" section later in this document.) 7. Low input voltage malfunction prevention circuit (U.V.L.O.) This circuit protects the system against degradation or destruction due to incorrect control operation when the power supply voltage falls during power on or power off. The low input voltage malfunction prevention circuit detects the internal reference voltage that changes with the supply voltage level. While the supply voltage is rising, this circuit cuts off the output drive transistor until the reference voltage reaches 1.67 V. It also sets the dead-time to 100 % and at the same time holds the S.C.P. pin (pin 1) and the DT pins (pins 2, 3, and 4) at 0 V, and the OSC pin (pin 17) at about 1.2 V. 8. PWM comparators The PWM comparators control the on-period of the output pulse according to their input voltage. The PWM 1 and PWM 2 comparators reverse the logic of their inputs when adjusting the on-period of their respective output. The output transistors are turned on during periods when the OSC pin (pin 17) triangular waveform is lower than both of the corresponding FB pin (pins 20, 22, or 24) and the corresponding DT pin (pins 2, 3, or 4). The maximum duty is set to 86 % internally, but can be set to a value in the range 0% to 100% by inserting a resistor between the DT pin and ground, or the DT pin and VREF pin. (See the "[6] Setting the maximum duty" section later in this document.) The IC's soft start function operates to gradually increase the width of the output pulse on-period during startup if a capacitor is inserted between the DT pin and ground. See the "[7] Setting the soft start time" section later in this document.
SDH00012BEB
17
AN8049SH
I Application Notes (continued)
[4] Function descriptions (continued) 9. Output 1 and output 2 blocks These output circuits have a totem pole structure. A constant-current source output with good line regulation can be set up freely by connecting current setting resistors to the RB pins (pins 10 and 11). See the "[2] Main characteristics" section earlier in this document for details on the RB vs. ISO(OUT) and RB vs. ISI(OUT) characteristics. 10. Output 3 block This output circuit has an open collector structure. An output current of up to 50 mA can be provided, and the output pin has a breakdown voltage of 14.2 V. 11. CTL block This block controls the on/off state of each channel. See the "[9] Sequential operation" section later in this document. [5] Time constant setup for the timer latch short-circuit protection circuit Figure 6 shows the structure of the timer latch short-circuit protection circuit. The short-circuit protection comparator continuously compares a 0.9 V reference voltage with the FB1, FB2, and FB3 error amplifier outputs. When the DC-DC converter output load conditions are stable, the short-circuit protection comparator holds its average value since there are no fluctuations in the error amplifier outputs. At this time, the output transistor Q1 will be in the conducting state, and the S.C.P. pin will be held at 0 V. If the output load conditions change rapidly and a high-level signal (0.9 V or higher) is input to the short-circuit protection comparator from the error amplifier output, the short-circuit protection comparator will output a low level and the output transistor Q1 will shut off. Then, the capacitor CSCP connected to the S.C.P. pin will start to charge. When the external capacitor CSCP is charged to about 1.26 V by the constant current of about 1.1 mA, the latch circuit will latch and the dead-time will be set to 100% with the output held fixed at the low level. Once the latch circuit has latched, the S.C.P. pin capacitor will be discharged to about 0 V, but the latch circuit will not reset unless either power is turned off or the power supply is re-started by on/off control. VSCP (V) t 1.26 V = ICHG x PE CSCP Short-circuit detection time tPE 1.26 t (s) = 1.15 x C (F)
PE SCP
At power supply startup, the output appears to be in the shorted state, and the IC starts to charge the S.C.P. pin capacitor. Therefore, users must select an external capacitor that allows the DC-DC converter output voltage to rise before the latch circuit in the later stage latches. In particular, care is required if the soft start function is used, since that function makes the startup time longer.
0.06 t (s) Figure 5. S.C.P. pin charging waveform
On/off control VCC FB1 FB2 FB3 24 22 20 S.C.P. comp. Q1 1.1 A U.V.L.O.
Internal reference voltage
Latch R Q S High level detection comparator VREF
Output shutoff
0.9 V 23 S.C.P. Figure 6. Short-circuit protection circuit
18
SDH00012BEB
AN8049SH
I Application Notes (continued)
[6] Setting the maximum duty The maximum duty is set to 86% internally to the IC. However, this setting can be changed to be any value in the range 0% to 100% by adding an external resistor. 1. To use a duty lower than the current duty (80% to 92%) Insert the resistor RDT between the DT pin and ground. Determine the DT pin voltage for the required duty from the provided DT pin voltage vs. maximum on-duty characteristics in the "[2] Main characteristics" section and determine the value of the external resistor RDT from formula A. Note that there is a sample-to-sample variation of -19% to +33% due to temperature characteristics and sampleto-sample variations of the internal resistors R1 and R2. (However, the direction of the sample-to-sample variations is identical for R1 and R2.) Determine the size of the sample-to-sample variations in the DT pin voltage VDT from formula B, and estimate the size of the sample-to-sample variation in the duty from the provided DT pin voltage vs. maximum on-duty characteristics in the "[2] Main characteristics" section . RDT = VDT VREF 1 1 -( + ) x VDT R1 R1 R2 R2 / RDT x VREF R1 + R2 / RDT **********A R1 **********B R2 VREF 1.26 V DT RDT R1 R2 ch.1, 2 45 k 55 k ch.3 44 k 56 k
VDT =
2. To use a duty higher than the current duty (80% to 92%) Insert the resistor RDT between the DT pin and the VREF pin. Use formulas C and D to determine the value of the external resistor RDT and the size of the sample-to-sample variations in the same manner as in item 1 above. VREF VREF - VDT 1.26 V RDT = **********C 1 1 VREF ( + ) x VDT - RDT R1 R1 R2 R1 VDT = R2 x VREF R2 + R1 / RDT **********D
R2 DT
[7] Setting the soft start time The soft start time is determined by the value of the capacitor connected between the DT pin and ground. OSC pin waveform DT pin waveform VDT
0.2 V Soft start time, tD Use the following formula to set the soft start time tD. VDT R x 1) tD = - R2 x CDT x ln (1 - VREF - VDT R2
R1 R2
VREF 1.26 V DT CDT
ch.1, 2 R1 R2 45 k 55 k
ch.3 44 k 56 k
SDH00012BEB
19
AN8049SH
I Application Notes (continued)
[8] Parallel synchronous operation of multiple ICs Multiple instances of this IC can be operated in parallel. If the OSC pins (pin 17) and OFF pins (pin 8) are connected to each other as shown in figure 7, the ICs will operate at the same frequency. It is also possible to operate a one-channel control IC (e.g. the AN8016SH or AN8016NSH) and a two-channel control IC (e.g. the AN8017SA or AN8018SA) in this parallel synchronous mode. In this case, short the OSC and Off pins together. OSC pins connected together
17 OSC
IC1
IC2
AN8049SH
AN8049SH
S.C.P. 1
Off 8
VREF 9
S.C.P. 1
17 Off 8
OSC
H L
Off pins connected together Figure 7. Slave operation circuit example
Notes on parallel operation: 1. The remote on/off state of each individual IC cannot be controlled independently. In this sort of circuit, always connect all the Off pins together, and control the on/off states of the multiple ICs at the same time. The reason for this is that if, for example, IC1 is solely turned on/off, the sawtooth wave will be stopped temporarily and the OSC pin held fixed at about 1.2 V. As a result the IC2 OUT1 to OUT3 pins will be forced temporarily to the full off-state and the DC-DC converter output voltage will fall. 2. All ICs are shut down when an output shorted state occurs. For example, if the IC1 output voltage falls, its output short-circuit protection circuit will operate, and the latch circuit will latch. When this happens, the IC1 output stops, and at the same time the sawtooth oscillator stops, and the OSC pin is held fixed at about 1.2 V. As a result, the IC2 OUT1 to OUT3 pins temporarily go to the full off-state, and the DC-DC converter output voltage will drop. Finally, the IC2 output short-circuit protection circuit will operate, and the latch will go to the latched state. This behavior will also occur if the IC2 output falls first.
20
SDH00012BEB
VREF 9
AN8049SH
I Application Notes (continued)
[9] Sequential operation Sequential operation under the control of external capacitors Delays can be provided in the startup times by inserting capacitors (CCTL) between the CTL pins and ground. Delay time: tDLY = 1.26 (V) x CCTL (F)/1.1 (A) (s)
AN8049SH
VCTL VCC CTL1 1.26 V CTL2 CTL3
CTL3 5
CTL2 6
CCTL3 CCTL2
CTL1 7
CCTL1 Stop ch.1 Start
CCTL1 < CCTL2 < CCTL3 ch.2
Stop
Start
Stop ch.3
Start
U.V.L.O. cleared Figure 8. Sequential operation using external capacitors
SDH00012BEB
21
AN8049SH
I Application Notes (continued)
[10] Notes on power supply printed circuit board design Careful attention must be paid to the following points when designing the printed circuit board layout to achieve low noise and high efficiency. 1. Use extremely wide lines for the ground lines, and isolate the IC ground from the power system ground. In particular, during light-load operation (when the on-duty is low) switching noise can enter the system at the lower limit of the sawtooth waveform causing the operating frequency to vary every period and resulting in unstable control. Take measures described as 1) and 2) below, and assure that switching noise does not appear on the sawtooth waveform. 1) Use a ground line separate from the power system ground for the capacitor and resistor connected to the OSC pin. 2) Lower the OSC pin impedance by either decreasing the value of the resistor RT or increasing the value of the capacitor CT. (See the figures below.)
VIN The frequency changes at each period. Small Large
OUT1 12
OSC 17
VOUT Q1 Lower limit voltage GND of the sawtooth wave during stable operation Common impedance
RT
CT
Noise is picked up and the IC switches from charge to discharge operation.
VIN
OUT1 12
OSC 17
VOUT Q1 GND
RT
CT
(2) Modify the values of the capacitor and resistor.
(1) Use separate lines.
2. Position input filter capacitors as close as possible to the VCC and ground pins. If switching noise cannot be suppressed even with exceptionally large capacitors, or if there are limitations on the size of capacitors that can be used, install an CR filter in the input to reduce switching noise. Problems may occur if switching noise enters the IC by any route. 3. Keep the length of the line between the OUT pin and the switching device as short as possible to provide a clean switching waveform to the switching device. 4. Use longer lines for the low-impedance side of the output voltage detection resistors.
22
SDH00012BEB
AN8049SH
I Application Notes (continued)
[11] Differences between this IC and the AN8049FHN The pin arrangements differ. The AN8049FHN is a alternative package version of this IC.
AN8049SH
OUT3
17
16
15
14 11 RB1
12 11 10 9 8
24
23
22
21
20
19
18
10
CTL1
Off
S.C.P.
CTL3
CTL2
VREF
RB2
DT3
DT2
DT1
AN8049FHN
19
18
17
16
15
14
VCC
FB2 IN-1 FB1 S.C.P. DT3
20 21 22 23 24
13
OUT3
IN-2
IN-3
IN+3
OSC
FB3
GND OUT2 OUT1 RB1 RB2
1
2
3
4
5
6
CTL3
CTL2
CTL1
Off
VREF
DT2
DT1
7
OUT1
12
1
2
3
4
5
6
7
8
9
13
OUT2
GND
IN-1
IN-2
IN-3
IN+3
OSC
VCC
FB1
FB2
FB3
SDH00012BEB
23
AN8049SH
I Application Notes (continued)
[12] Error amplifier frequency characteristics 1. Error amplifiers 1 and 2 (Test circuit)
100 k 10 F VIN 4 mV[p-p] 2.3 V 1 k
Gain (dB) Phase ()
40 30
IN-1 100 k
Amp.1
VOUT FB1
20 10 0 -10 -20 180 135
VREF 1.26 V
90
45
0
-45 1k
10k
100k
1M
10M
100M
2. Error amplifier 3 (Test circuit) 1V 10 F VIN 4 mV[p-p] 1 k IN-3
Amp.3 40 30
Frequency (Hz)
1 k IN+3 1 k
Gain (dB) Phase ()
FB3 VOUT
20 10 0 -10 -20 0 -45 -90 -135 -180 -225 1k
100 k 10 F
10k
100k
1M
10M
100M
Frequency (Hz)
24
SDH00012BEB
AN8049SH
I Application Circuit Example
Inverting VOUT3 150 k -15 V 10 mA Step-down VOUT1 23 k 3.3 V 300 mA 14 k Step-up VOUT2 13.3 V 300 mA
13 k
125.1 k
VREF
10 F
0.033 F
12 k
Q2 10 F
100 pF
2.2 k
Q1 1 k
13
Input 10 k 10 k
OUT2
GND 14 OUT3 15
0.12 F
10 F
470 pF
VCC 16 OSC 17
100 pF
12 OUT1 11 RB1
9.1 k 10 RB2 1 k 9 VREF
7.5 k
IN+3 18 IN-3 19 7 CTL1 6 CTL2 5 CTL3 4 DT1 3 DT2 2 DT3
0.01 F
FB3 20 IN-2 21
0.01 F
1 M
FB2 22 IN-1 23
0.12 F 0.12 F
0.01 F
1 M
FB1 24
0.12 F 1 S.C.P.
On/Off
0.12 F 8 Off
100
10 F
Q3
SDH00012BEB
25
AN8049SH
I Evaluation Board
1. The element numbers of the board pair with the ones of the circuit. 2. "JP" of the board shows the jumper. Short circuit. * Circuit
Input filter (When no using, short circuit the both ends of RIN1)
Input VIN 12 V
RC3 10 k
1 000 pF CC2 RC4 RC5 10 k 3 k LC1 330 H
QC1 QC2 DC1 CC1 10 F
CC4 RC1 0.47 F 150 k
Inverting VOUT3 -15 V 10 mA
CC1 0.033 F RC2 120 k
1 000 pF
RIN1
C24 0.012 F
C22 0.082 F
CIN1 1 F
LB1 100 H DB1 QB1 CB2 10 F CB3 0.47 F
20 FB3 C20
R15
C15
15 OUT3
18 IN+3
19 IN-3
21 IN-2
24 FB1
16 VCC
13 OUT2
14 GND
23 IN-1
0.056 F
R24 1 M
R22 1 M
17 OSC 3.6 k
0.012 F
CIN2
VREF Step-up VOUT2 15 V CB1 0.033 F 10 mA
RB1 142 k RB2 13 k
22 FB2
LA1 33 H
RB2 10
RB1 11
OUT1 12
CA1 DA1 QA1 CA2 33 F CA3 0.47 F RA1 125.1 k RA2 12 k
Step-up VOUT1 14.4 V 100 mA
DT3 2
DT1 4
CTL3 5
CTL2 6
CTL1 7
Off 8
S.C.P. 1
0.047 F
0.012 F
VREF 9
0.1 F
DT2 3
R10 9.1 k
C1
C2
C3
C4
C5
C6
C7
C9
R11 1 k
GND
On/Off
* Board
RIN1
LC1 DC1
CIN1 CC2 RC3 RC4 JP CIN2
C15 R15
OUT3
VIN
CC1 RC1
JP RC2
JP
GND
QC1 QC2 CC4
OUT2
CC3 JP GND
RC5 DB1 LB1
C20
RB2 JP C22
RB1 CB1 RA1 CA1
On/Off
R22 JP
CB3 CB2 DA1
OUT1
QB1
8049
R24 RA2 C24
LA1 QA1
JP
CA3 CA2 R11 R10 C9 C7 C6 C5 C4 C3 C2 C1
AN8049SH
26
SDH00012BEB
AN8049SH
I New Package Dimensions (Unit: mm)
* SSOP024-P-0300D (Lead-free package) 6.500.30 24 13
(1.00)
5.500.30 7.500.30
0.15-0.05
+0.10
0 to 10 (0.50) (0.50) 0.50
1.500.20 0.100.10
1
12 0.20+0.10 -0.05
Seating plane
Seating plane
SDH00012BEB
27
Request for your special attention and precautions in using the technical information and semiconductors described in this material
(1) An export permit needs to be obtained from the competent authorities of the Japanese Government if any of the products or technologies described in this material and controlled under the "Foreign Exchange and Foreign Trade Law" is to be exported or taken out of Japan. (2) The technical information described in this material is limited to showing representative characteristics and applied circuit examples of the products. It does not constitute the warranting of industrial property, the granting of relative rights, or the granting of any license. (3) The products described in this material are intended to be used for standard applications or general electronic equipment (such as office equipment, communications equipment, measuring instruments and household appliances). Consult our sales staff in advance for information on the following applications: * Special applications (such as for airplanes, aerospace, automobiles, traffic control equipment, combustion equipment, life support systems and safety devices) in which exceptional quality and reliability are required, or if the failure or malfunction of the products may directly jeopardize life or harm the human body. * Any applications other than the standard applications intended. (4) The products and product specifications described in this material are subject to change without notice for reasons of modification and/or improvement. At the final stage of your design, purchasing, or use of the products, therefore, ask for the most up-to-date Product Standards in advance to make sure that the latest specifications satisfy your requirements. (5) When designing your equipment, comply with the guaranteed values, in particular those of maximum rating, the range of operating power supply voltage and heat radiation characteristics. Otherwise, we will not be liable for any defect which may arise later in your equipment. Even when the products are used within the guaranteed values, redundant design is recommended, so that such equipment may not violate relevant laws or regulations because of the function of our products. (6) When using products for which dry packing is required, observe the conditions (including shelf life and after-unpacking standby time) agreed upon when specification sheets are individually exchanged. (7) No part of this material may be reprinted or reproduced by any means without written permission from our company.
Please read the following notes before using the datasheets
A. These materials are intended as a reference to assist customers with the selection of Panasonic semiconductor products best suited to their applications. Due to modification or other reasons, any information contained in this material, such as available product types, technical data, and so on, is subject to change without notice. Customers are advised to contact our semiconductor sales office and obtain the latest information before starting precise technical research and/or purchasing activities. B. Panasonic is endeavoring to continually improve the quality and reliability of these materials but there is always the possibility that further rectifications will be required in the future. Therefore, Panasonic will not assume any liability for any damages arising from any errors etc. that may appear in this material. C. These materials are solely intended for a customer's individual use. Therefore, without the prior written approval of Panasonic, any other use such as reproducing, selling, or distributing this material to a third party, via the Internet or in any other way, is prohibited.
2001 MAR

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