ICHAUS IC-DC

preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 1/19
FEATURES
APPLICATIONS
♦
♦
♦
♦
♦ Dual voltage supply by
buck/boost converters with
adjustable, back-end linear
regulators
♦ Power management for laser,
encoder, and automotive
applications
♦
♦
♦
♦
♦
♦
♦
♦
♦
♦
♦
Wide input voltage range of +4 to +36 V
Reverse polarity protection up to -36 V with autarky function
Universal buck/boost converter with high efficiency
Two back-end, adjustable linear regulators (1.5 V to 5.5 V) with
a total of up to 300 mA of output current and a separate output
voltage monitor
Low residual ripple with small capacitors in the µF range
Separate enable inputs for the linear regulators
Two switched linear regulator outputs
Integrated switching transistors and flyback diodes
Converter cut-off current can be set by an external resistor
Integrated 3 MHz oscillator with no external components
Active noise spectrum reduction
Error messaging with overtemperature, overvoltage, and
undervoltage at the current-limited open-collector output
Wide temperature range of -40 °C to 125 °C
Protective circuitry against ESD
Space saving 24-pin QFN package
PACKAGES
QFN24 4 mm x 4 mm
(RoHS compliant)
BLOCK DIAGRAM
LVBH
4...36V
CVB
1μF
CVBR
10μF
VB
22μH
VBR
VBL
VHL
VH
CVH
3.3μF
REVERSE
PROTECT.
VH1
INTERNAL
SUPPLY
VCC1
VBROK
VOLTAGE
MONITOR
NAUT
BUCK
POE1
1
AUTARKY
DETECT.
TOK
THERMAL
SHUTDOWN
BOOST
1
VH2
CONTROL
VCC2
BIAS
RREF
OSCILLATOR
REFERENCE
R1
VCC2
R3
1.5...5.5V
CVCC2
1μF
SUPPLY
SWITCH 2
LIN.-REG.2
V1OK
ENV2
OUTPUT
ENABLE
CFG1
CONFIGURATION
VCC1:
5V/3.3V/R1:R2
VCC2:
3.3V/2.5V/R3:R4
CFG2
R2
2
CVH2
3.3μF
VCC1,VCC2
ENV1
VCC1
POE2
2
SWITCHING REGULATOR
1.5...5.5V
CVCC1
1μF
SUPPLY
SWITCH 1
LIN.-REG.1
ERROR DETECT.
RREF
20k
CVH1
3.3μF
R4
Copyright © 2011 iC-Haus
1
V2OK
&
iC-DC
GNDA GND
2
VOLTAGE
MONITORING
TEST
http://www.ichaus.com
iC-DC
preliminary
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 2/19
DESCRIPTION
iC-DC is a monolithic switching converter with two
back-end linear regulators. The output voltages of
the two linear regulators can be individually pinconfigured within a range of 1.5 to 5.5 V. The switching converter supplies up to 300 mA which can be
drawn from the two linear regulators in the ratio required.
The back-end linear regulators have a very low residual ripple with comparatively small filter capacitors in
the single-digit µF range.
The intermediate voltages of the two on-chip linear
regulators are adjusted to minimize their drop-out
voltages. These are approximately 400 mV above the
set linear regulator output voltages.
The chip temperature, input voltage, and integrated
reverse polarity protection are monitored and errors
signaled by current-limited open-collector outputs.
With overtemperature the switching converter is disabled to reduce the chip’s power dissipation.
The high efficiency of the buck/boost converter for
an input voltage range of +4 V to +36 V makes iC-DC
suitable for industrial applications. Using very few external components, a DC/DC power pack can be created with a stabilized supply voltage and minimum
power dissipation.
iC-DC is ideal for sensor applications thanks to its
minimal power loss, few components, and stabilized
supply. Switching transistors, flyback diodes, and an
oscillator are integrated in the device so that the only
external elements needed are an inductor, the backup capacitors, and a reference resistor.
By using two independent regulators voltages can be
decoupled from sensitive analog circuits and driver
devices, for example.
The linear regulator output voltages are monitored
and once having reached the steady state they are
also switched to outputs POE1 and POE2. The output voltages of the two linear regulators VCC1 and
VCC2 can be switched on and off by two separate
inputs.
The device’s standby function can be activated to
minimize the current consumption.
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 3/19
CONTENTS
PACKAGES
PACKAGE DIMENSIONS . . . . . . . . . . .
4
5
ABSOLUTE MAXIMUM RATINGS
6
THERMAL DATA
6
ELECTRICAL CHARACTERISTICS
7
DESCRIPTION OF FUNCTIONS
Charge/discharge phase . . . . .
Intermittent flow / continuous flow
Startup behavior . . . . . . . . .
Standby . . . . . . . . . . . . . .
.
.
.
.
11
11
12
12
12
LINEAR REGULATORS VCC1 AND VCC2
Switched output voltages . . . . . . . . . . .
Voltage monitor self-test . . . . . . . . . . . .
Current carrying capacity . . . . . . . . . . .
13
13
13
13
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
REVERSE POLARITY PROTECTION
14
ERROR EVALUATION
15
Supply voltage monitor . . . . . . . . . . . . .
15
Output voltage monitor . . . . . . . . . . . . .
15
Output voltage monitor self-test . . . . . . . .
15
Temperature monitor . . . . . . . . . . . . . .
15
AUTARKY FUNCTION
15
DESCRIPTION OF THE APPLICATION
16
Selecting the coil . . . . . . . . . . . . . . . .
16
Selecting the capacitors . . . . . . . . . . . .
16
Printed circuit board layout . . . . . . . . . .
16
EXAMPLE APPLICATION
17
DESIGN REVIEW: Notes On Chip Functions
17
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 4/19
PACKAGES
PIN CONFIGURATION
QFN24-4x4 (4 mm x 4 mm)
24
23
22
PIN FUNCTIONS
No. Name Function
21
20
1 RREF
2 GNDA
3 CFG1
19
1
18
2
17
3
16
DC
...
yyww...
4
5
6
7
8
9
10
11
15
14
13
12
Reference Resistor
Analog Ground
VCC1 Configuration 3.3/5.0 V or
1.5 V to 5.5 V with ext. R Divider
4 CFG2 VCC2 Configuration2.5/3.3 V or
1.5 V to 5.5 V with ext. R Divider
5 TEST Test Input
6 POE2 Power Output Enable VCC2 Voltage
7 V2OK Error Output VCC2 Voltage
8 VCC2 1.5 V to 5.5 V Lin. Regulator Output 2
9 VH2
Intermediate Voltage 2
for VCC2 Regulator
10 VH1
Intermediate Voltage 1
for VCC1 Regulator
11 VCC1 1.5 V to 5.5 V Lin. Regulator Output 1
12 V1OK Error Output VCC1 Voltage
13 POE1 Power Output Enable VCC1 Voltage
14 VH
Intermediate Voltage
15 VHL
Inductor Terminal VH
16 GND
Power Ground
17 VBL
Inductor Terminal VB
18 VBR
Reverse Protected Supply Voltage
19 VB
+4 V to +36 V Supply Voltage
20 ENV1 VCC1 Linear Regulator Activation
21 ENV2 VCC2 Linear Regulator Activation
22 VBROK Error Output Supply Voltage
23 TOK
Error Output Overtemperature
24 NAUT Error Output Autarky
TP
Thermal Pad
The Thermal Pad on the underside of the package should be appropriately connected to GND for better heat
dissipation (ground plane). GNDA should also be directly connected to neutral point GND. Ground loops should
be avoided.
Only the Pin 1 mark on the front or reverse is determinative for package orientation (
subject to change).
DC and code are
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 5/19
PACKAGE DIMENSIONS
RECOMMENDED PCB-FOOTPRINT
3.80
2.49
15
R0.
TOP
0.30
0.70
0.50
0.25
0.40
3.80
0.90
2.49
SIDE
BOTTOM
2.45
4
2.45
4
0.50
dra_qfn24-1_pack_1, 10:1
All dimensions given in mm.
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 6/19
ABSOLUTE MAXIMUM RATINGS
Maximum ratings do not constitute permissible operating conditions; functionality is not guaranteed. Exceeding the maximum ratings can
damage the device.
Item
No.
Symbol
Parameter
Conditions
Unit
Min.
Max.
G001 V()
Voltage at VB
-40
42
V
G002 V()
Voltage at VBR, VBL, ENV1, ENV2
-0.3
42
V
G003 V()
Voltage at VHL, VH, VBROK, NAUT,
TOK, TEST
-0.3
8.4
V
G004 V()
Voltage at VH1, VH2
-0.3
6.4
V
G005 V()
Voltage at VCC1, VCC2, V1OK, V2OK,
CFG1, CFG2, POE1, POE2, RREF,
GNDA
-0.3
5.6
V
G006 I(VB)
Current in VB
-50
800
mA
G007 I(VBR)
Current in VBR
-50
800
mA
G008 I(VBL)
Current in VBL
-800
50
mA
G009 I(VHL)
Current in VHL
-50
800
mA
G010 I()
Current in VH, VH1, VH2, VCC1, VCC2
-500
20
mA
G011 I()
Current in CFG1, CFG2, ENV1, ENV2,
V1OK, V2OK, VBROK, NAUT, TOK,
POE1, POE2, RREF, TEST, GNDA
-20
20
mA
G012 Vd()
ESD Susceptibility at all pins
2
kV
G013 Tj
Chip-Temperature
-40
150
°C
G014 Ts
Storage Temperature Range
-40
150
°C
HBM, 100 pF discharged through 1.5 kΩ
THERMAL DATA
Operating conditions: VB = +4 V to +36 V
Item
No.
Symbol
Parameter
Conditions
Unit
Min.
T01
Ta
Operating Ambient Temperature Range
T02
Rthja
Thermal Resistance Chip to Ambient
QFN24
Typ.
-40
Surface mounted, Thermal-Pad soldered to
approx. 2 cm² copper area on the PCB
All voltages are referenced to ground (pin GND: power ground) unless otherwise stated.
All currents flowing into the device pins are positive; all currents flowing out of the device pins are negative.
30
Max.
125
°C
40
K/W
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 7/19
ELECTRICAL CHARACTERISTICS
Operating conditions: VB = +4 V to +36 V, RREF = 20 kΩ ±1 %, Tj = -40°C to +125°C, reference is GND (GNDA = GND),
unless otherwise stated.
Item
No.
Symbol
Parameter
Conditions
Unit
Min.
Typ.
Max.
Total Device
001
VB
Permissible Supply Voltage
36
V
002
003
I()
Supply Current in VB
ENV1 = lo, ENV2 = lo, standby
20
100
200
µA
I()
Supply Current in VB
only one Linear Regulator active,
no load current, no external voltage divider
VB = 24 V
VB = 12 V
VB = 4 V
1.5
2.5
10
3
5.5
22
8
15
50
mA
mA
mA
both Linear Regulators active, no load current,
no external voltage divider
VB = 24 V
VB = 12 V
VB = 4 V
2
3
12
4
7
25
10
20
60
mA
mA
mA
V() = 2...36 V
15
150
µA
2
V
004
I()
Supply Current in VB
4
007
Ipd()
Pull-Down Current in ENV1,
ENV2
009
Vt()hi
Input Threshold Voltage hi at
ENV1, ENV2
010
Vt()lo
Input Threshold Voltage lo at
ENV1, ENV2
011
Vt()hys
Input Hysteresis at ENV1, ENV2 Vt()hys = Vt()hi − Vt()lo
100
400
mV
012
Vc()lo
Clamp Voltage lo at all pins with
exception of VB
versus GND, I() = -10 mA
-1.4
-0.3
V
013
Vc()lo
Clamp Voltage lo at VB
versus GND, I() = -2 mA
-60
-42
V
014
Vc()hi
Clamp Voltage hi at VB VBR,
VBL, ENV1, ENV2
versus GND, I() = 2 mA
42
60
V
015
Vc()hi
Clamp Voltage hi at VBROK,
NAUT, TOK, TEST
versus GND, I() = 1 mA
9
18
V
016
Vc()hi
Clamp Voltage hi at VH
versus GND, I() = 5 mA
8.3
18
V
017
Vc()hi
Clamp Voltage hi at VH1, VH2
versus GND, I() = 10 mA
6.2
18
V
018
Vc()hi
Clamp Voltage hi at VCC1,
VCC2, POE1, POE2, CFG1,
CFG2
versus GND, I() = 10 mA
5.6
18
V
019
Vc()hi
Clamp Voltage hi at GNDA,
RREF
versus GND, I() = 10 mA
2.5
18
V
020
Vc()hi
Clamp Voltage hi at V1OK, V2OK V1OK versus VCC1, V2OK versus VCC2,
I() = 2 mA
0.3
1.4
V
021
Vc()hi
Clamp Voltage hi at VHL
0.3
1.4
V
0.6
V
0
mA
0.8
versus VH, I() = 10 mA
V
200
Reverse Polarity Protection VB, VBR and Autarky Detection NAUT
Vs(VBR)hi = VB − V(VBR), I(VBR) = -100 mA
101
Vs()hi
Saturation Voltage hi at VBR
103
Izu()
Maximum Permissible Current hi V(VBR) = 0...3 V, VB increasing
from VBR at Startup
104
Imax()
Maximum Current from VBR
V(VBR) = 2 V...VB − 0.6 V
-500
-120
mA
105
Imax()
Maximum Current from VBR
V(VBR) = 0 V
-150
-10
mA
108
Ir()
Leakage Current from VB at
Autarky
VBR > VB + 50 mV
-0.5
0
mA
109
d(VB,VBR) Voltage Difference for Autarky
VBR versus VB; NAUT = lo
25
12.5
0
mV
110
Ir,max()
Maximum Current from VB
VB < VBR < VB + 50 mV
-10
-4
0
mA
111
Ir()
Reverse Current from VB
-36V < VB < GND
-1
0
mA
112
Vs()lo
Saturation Voltage lo at NAUT
I(NAUT) = 5 mA, NAUT = lo
113
Isc()lo
Short-Circuit Current lo in NAUT V(NAUT) = 2...8 V, NAUT = lo
114
Ilk()
Leakage Current in NAUT
V(NAUT) = 0...8 V, NAUT = hi
0.3
-5
-250
10
-10
0.4
V
20
mA
10
µA
3.95
V
Voltage Monitoring VBR and Error Detection VBROK
201
Vt1()hi
Lower Turn-on Threshold VBR
VBR increasing, VBROK: lo → open
202
Vt1()lo
Lower Turn-off Threshold VBR
VBR decreasing, VBROK: open → lo
3.75
2.8
3.15
V
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 8/19
ELECTRICAL CHARACTERISTICS
Operating conditions: VB = +4 V to +36 V, RREF = 20 kΩ ±1 %, Tj = -40°C to +125°C, reference is GND (GNDA = GND),
unless otherwise stated.
Item
No.
Symbol
Parameter
Conditions
Unit
Min.
Typ.
Max.
203
Vt1()hys
Hysteresis VBR
Vt1()hys = Vt1()hi − Vt1()lo
204
Vt2()hi
Overvoltage Detection at VBR
VBR increasing,
VBROK: open → lo
205
Vt2()lo
Reset Overvoltage Detection at
VBR
VBR decreasing,
VBROK: lo → open
35
37.6
206
Vt2()hys
Hysteresis VBR
Vt2()hys = Vt2()hi − Vt2()lo
1
2.8
210
Vs()lo
Saturation Voltage lo at VBROK
I(VBROK) = 5 mA, VBROK = lo
0.4
V
211
Isc()lo
Short-Circuit Current lo in
VBROK
V(VBROK) = 2..8 V, VBROK = lo
50
mA
212
Ilk()
Leakage Current in VBROK
V(VBROK) = 0..8 V, VBROK = hi
-10
10
µA
213
V(VBR)
Minimal Supply Voltage for
VBROK Function
I(VBROK) = 5 mA, VBROK = lo,
Vs(VBROK)lo < 0.4 V
3.2
Switching Regulator VH, VH1, VH2
305 V()
Voltage at VH
LVBH = 22 µH ±20 %, Ri(LVBH) < 1.1 Ω,
CVH = 1 µF;
VB ≤ 5 V, I(VH) = -50 mA,
VB > 5 V, I(VH) = -100 mA,
VB ≥ 12 V, I(VH) = -200 mA,
VB ≥ 24 V, I(VH) = -300 mA
tolerance ±30 %
300
600
40.4
7
7.25
7.25
7.25
mV
42
V
V
4
V
V
7.75
7.75
7.75
7.75
8
8
8
8
1
V
V
V
V
307
CVH
Required Capacitor at VH
308
RiVH
Permissible Internal Resistance
of Capacitor at VH
309
V()
Voltage at VH1
versus VCC1, CVH1 = 1 µF,
VB ≤ 5 V, I(VH1) = -50 mA,
VB > 5 V, I(VH1) = -100 mA,
VB ≥ 12 V, I(VH1) = -200 mA,
VB ≥ 24 V, I(VH1) = -300 mA
311
CVH1
Required Capacitor at VH1
tolerance ±30 %
312
RiCVH1
Permissible Internal Resistance
of Capacitor at VH1
313
V()
Voltage at VH2
versus VCC2, CVH2 = 1 µF,
VB ≤ 5V, I(VH2) = -50 mA,
VB > 5 V, I(VH2) = -100 mA,
VB ≥ 12 V, I(VH2) = -200 mA,
VB ≥ 24 V, I(VH2) = -300 mA
315
CVH2
Required Capacitor at VH2
tolerance ±30 %
316
RiCVH2
Permissible Internal Resistance
of Capacitor at VH2
330
ηVH
Efficiency of Switching Converter VB = 4 V, V(VH) > 7 V, VB = VBR,
VH
VH1 > VCC1 + 800 mV, VH2 > VCC2 + 800 mV
70
%
331
ηVH
Efficiency of Switching Converter VB = 6.5 V, V(VH) > 7 V, VB = VBR,
VH
VH1 > VCC1 + 800 mV, VH2 > VCC2 + 800 mV
80
%
332
ηVH1
Efficiency of Switching Converter VB = 4 V, V(VH) > 8.1 V, VB = VBR,
VH1
ENV1 = hi, ENV2 = lo
70
%
333
ηVH1
Efficiency of Switching Converter
VH1
80
%
334
ηVH2
Efficiency of Switching Converter VB = 4 V, V(VH) > 8.1 V, VB = VBR,
VH2
ENV1 = lo, ENV2 = hi
70
%
335
ηVH2
Efficiency of Switching Converter VB = 6.5 V, V(VH) > 8.1 V, VB = VBR,
VH2
ENV1 = lo, ENV2 = hi
80
%
300
µF
400
1
Ω
600
mV
1
300
µF
400
1
Ω
600
mV
1
µF
1
Ω
Bias, Oscillator and Reference RREF
401
V()
Voltage at RREF
resistor RREF = 20 kΩ ±1 %,
resistor RREF versus GNDA
1.18
1.24
1.3
V
402
R()
Permissible Resistor at RREF
±1 %
19.6
34
kΩ
403
Isc()
Short-Circuit Current lo in RREF V(RREF) = 0 V
-3
-0.5
mA
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 9/19
ELECTRICAL CHARACTERISTICS
Operating conditions: VB = +4 V to +36 V, RREF = 20 kΩ ±1 %, Tj = -40°C to +125°C, reference is GND (GNDA = GND),
unless otherwise stated.
Item
No.
404
Symbol
Parameter
Conditions
Unit
Min.
fos
Oscillator Frequency
Linear Regulator VCC1
501 VCC1nom,hi Output Voltage
resistor RREF = 20 kΩ ±1 %,
resistor RREF versus GNDA
2
Max.
7
MHz
CFG1 = VCC1;
VB < 5 V, I(VCC1) = -60...10 mA,
VB ≥ 5 V, I(VCC1) = -100...10 mA,
VB ≥ 6.5 V, I(VCC1) = -150...10 mA,
VB ≥ 12 V, I(VCC1) = -200..10 mA,
VB ≥ 24 V, I(VCC1) = -250...10 mA
4.75
5
5.25
V
CFG1 = GNDA;
VB < 5 V, I(VCC1) = -100...10 mA,
VB ≥ 5 V, I(VCC1) = -150...10 mA,
VB ≥ 6.5 V, I(VCC1) = -200...10 mA,
VB ≥ 16 V, I(VCC1) = -300...10 mA,
VB ≥ 24 V, I(VCC1) = -350...10 mA,
3.135
3.3
3.465
V
502
VCC1nom,lo Output Voltage
503
Vr(CFG1)
Transmission Ratio of external
V(VCC1) =
Voltage Divider R(VCC1/CFG1) / (1 + R(VCC1/CFG1) / R(CFG1/GNDA)) *
R(CFG1/GNDA)
V(RREF),
R(VCC1/CFG1) + R(CFG1/GNDA) =
10 kΩ...50 kΩ ±1 %, V(VCC1) = 1.5...5.5 V
504
CVCC1
Required Capacitor at VCC1
versus GNDA
505
RiCVCC1
Permissible Internal Resistance
of Capacitor at VCC1
506
VCC1,lir
Line Regulation
I(VCC1) = -100 mA, VB = 8...30 V
507
VCC1,lor
Load Regulation
VB = 24 V, I(VCC1) = 0...200 mA
508
VCC1rip
Output Ripple
I(VCC1) = -100mA
Linear Regulator VCC2
601 VCC2nom,hi Output Voltage
Typ.
tolerance ±30 %
0.2
3.5
1
µF
1
Ω
-20
20
mV
-20
20
10
mV
mVpp
CFG2 = VCC2;
VB < 5 V, I(VCC2) = -100...10 mA,
VB ≥ 5 V, I(VCC2) = -150...10 mA,
VB ≥ 6.5 V, I(VCC2) = -200...10 mA,
VB ≥ 16 V, I(VCC2) = -300...10 mA,
VB ≥ 24 V, I(VCC2) = -350...10 mA
3.135
3.3
3.465
V
CFG2 = GNDA;
VB < 5 V, I(VCC2) = -150...10 mA,
VB ≥ 5 V, I(VCC2) = -200...10 mA,
VB ≥ 6.5 V, I(VCC2) = -250...10 mA,
VB ≥ 12 V, I(VCC2) = -300...10 mA,
VB ≥ 24 V, I(VCC2) = -350...10 mA
2.375
2.5
2.625
V
602
VCC2nom,lo Output Voltage
603
Vr(VCC2)
Transmission Ratio of external
V(VCC2) =
Voltage Divider R(VCC2/CFG2) / (1 + R(VCC2/CFG2) / R(CFG2/GNDA)) *
R(CFG2/GNDA)
V(RREF),
R(VCC2/CFG2) + R(CFG2/GNDA) =
10 kΩ...50 kΩ ±1 %, V(VCC2) = 1.5...5.5 V
604
CVCC2
Required Capacitor at VCC2
versus GNDA
605
RiCVCC2
Permissible Internal Resistance
of Capacitor at VCC2
606
VCC2,lir
Line Regulation
I(VCC2) = -100 mA, VB = 8...30 V
607
VCC2,lor
Load Regulation
VB = 24 V, I(VCC2) = 0...200 mA
608
VCC2rip
Output Ripple
I(VCC2) = -100mA
tolerance ±30 %
0.2
3.5
1
µF
1
Ω
-20
20
mV
-20
20
mV
10
mVpp
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 10/19
ELECTRICAL CHARACTERISTICS
Operating conditions: VB = +4 V to +36 V, RREF = 20 kΩ ±1 %, Tj = -40°C to +125°C, reference is GND (GNDA = GND),
unless otherwise stated.
Item
No.
Symbol
Parameter
Conditions
Unit
Min.
Typ.
Max.
Voltage Monitoring V1OK, V2OK (x = 1, 2)
701
VtU()lo
Lower Undervoltage Threshold
VCCx for VxOK = lo
versus VCCxnom
90
92
94
%VCC2
702
VtU()hi
Upper Undervoltage Threshold
VCCx for VxOK = hi
versus VCCxnom
91
93
95
%VCC2
703
VtO()lo
Lower Overvoltage Threshold
VCCx for VxOK = hi
versus VCCxnom
105
107
109
%VCC2
704
VtO()hi
Upper Overvoltage Threshold
VCCx for VxOK = lo
versus VCCxnom
106
108
110
%VCC2
705
Vt()hys
Hysteresis Under-/Overvoltage
VCCx
versus VCCxnom
0.25
1
1.5
%VCC2
706
Vs()lo
Saturation Voltage lo
VxOK = lo;
I() = 4 mA, VCCx ≥ 3 V
I() = 1 mA, VCCx < 3 V
0.4
0.4
V
V
Vs()hi = VCCx − V(), VxOK = hi;
I() = -4 mA, VCC2 ≥ 3 V
I() = -1 mA, VCC2 < 3 V
0.4
0.4
V
V
6
1
80
30
mA
mA
-100
-30
-6
-1
mA
mA
707
708
709
Vs()hi
Isc()lo
Isc()hi
Saturation Voltage hi
Short-Circuit Current lo
Short-Circuit Current hi
V() = VCCx, VxOK = lo;
VCCx ≥ 3 V
VCCx < 3 V
V() = 0 V, VxOK = hi;
VCCx ≥ 3 V
VCCx < 3 V
Supply Switches POE1, POE2 (x = 1, 2)
801
Vs()hi
Saturation Voltage hi
Vs()hi = VCCx − V(POEx);
V(VCCx) ≥ 2.5 V, I(POEx) = -10 mA,
V1OK, V2OK = hi
0.2
V
802
Vs()hi
Saturation Voltage hi
Vs()hi = VCCx − V(POEx);
V(VCCx) < 2.5 V; I(POEx) = -5 mA,
V1OK, V2OK = hi
0.2
V
803
Isc()hi
Short-Circuit Current hi
V(POEx) = 0 V; V(VCCx) ≥ 2.5 V,
POEx = hi, V1OK, V2OK = hi
-40
-12
mA
804
Isc()hi
Short-Circuit Current hi
V(POEx) = 0 V; V(VCCx) < 2.5 V,
POEx = hi, V1OK, V2OK = hi
-30
-6
mA
Thermal Shutdown and Error Detection TOK
901
Toff
Thermal Shutdown Threshold
150
160
175
°C
902
Ton
Restart Temperature
135
150
165
°C
903
Thys
Temperature Hysteresis
Thys = Toff − Ton
5
10
20
°C
904
Vs()lo
Saturation Voltage lo
I(TOK) = 5 mA; TOK = lo
905
Isc()lo
Short-Circuit Current lo
V(TOK) = 2..8 V; TOK = lo
906
lk()
Leakage Current
V(TOK) = 0..8 V; TOK = hi
10
-10
0.4
V
20
mA
10
µA
0.7
V
Test Input TEST
A01
Vt()hi
Threshold Voltage hi for Comparator test
A02
Vt()lo
Threshold Voltage lo for Comparator test
A03
Vt()hys
Hysteresis at TEST
A05
Ipd()
Pull-Down Current in TEST
A07
A08
0.64
0.54
0.6
Vt() = Vt(TEST)hi − Vt(TEST)lo
10
40
V() = 5.5 V
20
tsu(TEST) Settling Time at V1OK, V2OK
V1OK, V2OK changing hi → lo
10
tsu(TEST) Settling Time at V1OK, V2OK
V1OK, V2OK changing of lo → hi
2
V
100
mV
200
µA
20
30
µs
4
8
µs
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 11/19
DESCRIPTION OF FUNCTIONS
DC/DC converter iC-DC generates two regulated voltages of VH1 and VH2 from voltage VBR. These prestabilize the two linear regulators VCC1 and VCC2. A
third voltage of VH, also regulated, is generated to
drive these linear regulators. Voltage supply VB may
be either above or below the output voltages. Figure 1
shoes the basic function principle of iC-DC. Switches
S1 to S6 and diode D1 have been implemented on the
chip. The inductor, capacitors, and load resistors are
external devices.
S4
VB
D1
VBR
S1
VBL
S3
LVBH
VHL
S5
VH
RVH
CVH1
RVH1
CVH2
RVH2
VH1
S2
S6
CVH
VH2
Another feature of iC-DC is that bias voltages VH1 and
VH2 adjust themselves automatically to approximately
400 mV using the selected VCC1 or VCC2 voltage.
This results in minimum power dissipation as only a
low amount of voltage is lost through each of the linear
regulators.
Charge/discharge phase
During the charge phase switches S1 and S2 close
with the internal clock. A linearly increasing current
flows through coil LVBH. The energy from supply VBR
is stored in the coil’s magnetic field.
Switches S1 and S2 open for discharging. Switch S3
and one of the switches S4 /S5 /S6 are closed. The current can continue to flow in the coil and is supplied to
the relevant capacitor and relevant load. Figure 2 describes the resulting course of the current and voltage.
The current rise and fall times depend on the inductor
voltage.
Figure 1: Principle of operation of the converter
Dual 3.3V/5V BOOST/BUCK SMPS, 05.05.2008 11:51:33
400mA
300mA
200mA
100mA
0
I(LVBH)
4V
3V
2V
1V
0
-1V
V(VBL)
8V
6V
4V
2V
0
8.887ms
8.888ms
8.889ms
Time (linear) [Plot 0]
V(VHL)
Figure 2: Converter current/voltage characteristics (VB = 4 V)
8.89ms
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 12/19
Intermittent flow / continuous flow
If the inductor is recharged in the next cycle before the
coil current has run free, there is no gap in the current.
This continuous flow occurs when the supply voltage
is low or the load current high.
If the charge and discharge processes are concluded
within one clock cycle and the coil current drops to zero
each time, intermittent flow prevails. This is the case
when the supply voltage is sufficiently high or the load
current sufficiently low.
When no more current flows through the coil, after flyback in intermittent operation both ends of the inductor
are switched to ground. This prevents the oscillations
in no-load operation that are typical of many converters
(RLC resonating circuit). This helps to achieve better
EMC behavior.
Startup behavior
During startup and with low supply voltages the coil’s
maximum cut-off current is reduced (soft start) until the
nominal voltage is reached at VH. Figure 3 shows the
startup behavior for VH, VCC1 (5 V), and VCC2 (3.3 V)
with the voltage monitor outputs V1OK and V2OK.
ductor, the sequence must allow that all three converter outputs are respectively supplied with the required current. The core of the converter consists of
three independent converters. Each converter has its
own regulated cut-off and restart current and its own
voltage monitor. During the startup phase the VH converter ramps up until a voltage of approximately 7 V is
obtained. Here, the cut-off current is initially limited to
lower values so that a soft start with a low startup current ripple is achieved.
When a high enough VH voltage is available, the VH1
and VH2 converters are also switched on and the voltages rise to their nominal values. Once in a steady
state, the individual converters are cyclically supplied
by the inductor with precisely the amount of current
that is required at that moment. The maximum load
current can thus be drawn from each of the voltages
VH, VH1, VH2, VCC1, or VCC2.
Standby
The converters can be individually activated by pins
ENV1 and ENV2. If neither of the two inputs are triggered, the device is in standby mode and the current
consumption is reduced to a minimum. As soon as
one of the two inputs becomes active, the VH voltage
is also available.
As three output voltages are generated with this
switching converter topology using just one single inDual 3.3V/5V BOOST/BUCK SMPS, 08.05.2008 08:51:13
600mA
400mA
200mA
0
I(LVBH)
5V
4V
3V
2V
1V
0
V(V1OK)
V(V2OK)
8V
6V
4V
2V
0
500us
V(VH)
V(VCC1)
550us
Time (linear) [Plot 0]
600us
V(VCC2)
Figure 3: Startup principle for voltages VH, VCC1, VCC2, V1OK, and V2OK
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 13/19
LINEAR REGULATORS VCC1 AND VCC2
To achieve as low an interference voltage as possible,
even with small filter capacitors CVH1 and CVH2 , an independent linear regulator is connected after each of
the intermediate voltages VH1 und VH2.
Output voltages VCC1 and VCC2 can each be adjusted using a voltage divider at CFG1 and CFG2
within a range of 1.5 to 5.5 V ±5 % and according to
Equations 1 and 2.
V VCC1 = V (RREF ) × (1 +
R1
)
R2
(1)
V VCC2 = V (RREF ) × (1 +
R3
)
R4
(2)
and
NB: R1 + R2 bzw. R3 + R4 = 10 kΩ bis 50 kΩ
Inputs CFG1 and CFG2 can also be directly connected
to the relevant output voltage VCCx or GNDA. The resulting voltages are given in Tables 4 and 5.
VCC1 output voltage
Potential at CFG1
VCC1
GNDA
VCC1
Voltage divider
3.3 V
5.0 V
1.5 V to 5.5 V
Table 4: VCC1 settings
ulators are deactivated, iC-DC is in standby mode (see
DESCRIPTION OF FUNCTIONS/Standby).
Switched output voltages
The two pins POE1 and POE2 are triggered by monitor
outputs V1OK and V2OK and provide voltages drawn
from VCC1 or VCC2. This enables the supply of specific circuitry in a component group (e.g. EEPROMs) to
be switched on only after VCC1 or VCC2 have reached
their steady state.
Voltage monitor self-test
Using pin TEST the voltage monitoring comparators at
V1OK and V2OK can be tested during ongoing operation. The undervoltage and overvoltage thresholds of
V1OK and V2OK are checked in turn with each test.
For this purpose, pin TEST is increased to above the
threshold voltage by an external driver. Correct functioning is signaled by low signals at pins V1OK and
V2OK. The function of the connected POE1 and POE2
outputs remains unaffected.
Current carrying capacity
iC-DC’s current carrying capacity depends on set output voltage VCCx and input voltage VB. Figure 4
shows the current carrying capacity dependent on the
input voltage for various output voltages, measured
on the iC-DC EVAL DC1D evaluation board. The internal reverse polarity protective circuit was bridged
(VB = VBR) to increase the current carrying capacity.
VCC2 output voltage
VCC2
GNDA
VCC2
Voltage divider
2.5 V
3.3 V
1.5 V to 5.5 V
Table 5: VCC2 settings
The regulators have been compensated internally so
that they are stable in no-load operation without an external capacitor. Stability across the entire load range
is guaranteed by the minimum capacitances for CVCC1
and CVCC2 given in the electrical characteristics. The
outputs are current limited to protect them against destruction in the event of a short circuit.
The two linear regulators can be switched on and off
independently by inputs ENV1 and ENV2. If both reg-
0,500
0,450
0,400
0,350
Load Current [mA]
Potential at CFG2
0,300
0,250
0,200
0,150
VH (>7.2V)
5V VCCx
3,3V VCCx
2,5V VCCx
1,5V VCCx
0,100
0,050
0,000
0,0
5,0
10,0
15,0
20,0
25,0
30,0
35,0
40,0
Input Voltage VB [V]
Figure 4: Current carrying capacity for various output voltages dependent on VB (VB = VBR)
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 14/19
REVERSE POLARITY PROTECTION
LVBH
A protective switch inserted between supply VB and
pin VBR protects the entire system against reverse polarity. This can also be used to implement an Autarky
function (see AUTARKY FUNCTION). By connecting
VB to VBR the reverse polarity protection circuit can be
bridged to improve the current carrying capacity and
the overall efficiency, especially if low supply voltages
are used (Figure 5).
24V
CVB
1μF
22μH
VBR
VBL
VHL
REVERSE
PROTECT.
INTERNAL
SUPPLY
VBROK
BUCK
VOLTAGE
Figure 6: Protection against
MONITOR reverse polarity active,
NAUT
CVBR
for VB
= 24 V
AUTARKY
BOOST
22μH
1
DETECT.
VB
VBR
VBL
VHL
TOK
4V
CVB
1μF
REVERSE
PROTECT.
VBROK
VOLTAGE
VH
CVBR
ERROR DETECT.
RREF
RREF
20k
BUCK
DETECT.
VCC1
CONTROL
The reverse polarity
protection
switch is current limERROR
DETECT.
ited to the maximum mean current consumption of the
BIAS
system (Electrical Characteristics
104). A capacitor
(CVBR) must
be connected
to
pin
VBR if higher coil
RREF
OSCILLATOR
cut-off
currents
are
to
be
supplied.
REFERENCE
RREF
SWITCHING REGULATOR
This20k
capacitor should have a value of at least 1 µF at
a supply voltage
of VB = 24 V (Figure 6). With very
ENV1
OUTPUT
small supplyENV2
voltages
the value must be greater in orENABLE
VCC1
der toVCC2
cater for the higher power consumption during
CONFIGURATION
startup. The voltage
at VBR must no longer drop below
R1
VCC1:
R3
5V/3.3V/R1:R2
CFG1
the lower shutdown
threshold (Electrical CharacterisVCC2:
CFG2
tics
202)
to
ensure
safe
converter startup. A capacitor
3.3V/2.5V/R3:R4
R2
of approx.
10
µF
should
thus be selected for CVBR at
R4
GNDA GND
a supply voltage of VB = 4 V (Figure 7).
iC-DC
ENV1
VCC2
R1 Figure
R3
LIN.-REG.1
ENV2
VBROK
VH1
VBL
VBR
VHL
CVH1
3.3μF
OSCILLATOR
VCC1 REGULATOR
SWITCHING
REFERENCE
REVERSE
PROTECT.
1
CVH
3.3μF
22μH
10μF
BIAS
Figure 5: Protection against
MONITOR reverse polarity bridges
NAUT
VB
to VBR AUTARKY
BOOST
THERMAL
SHUTDOWN
LVBH
CONTROL
THERMAL
SHUTDOWN
VB
INTERNAL
SUPPLY
TOK
CVBR
1μF
VB
LVBH
4...36V
CVB
1μF
INTERNAL
1
SUPPLY
OUTPUT
ENABLE
POE1
SUPPLY
SWITCH 1
CONFIGURATION
VOLTAGE
BUCK
VH2
7: Protection
against
MONITOR reverse polarity active,
VCC1:
CVH2
5V/3.3V/R1:R2
CFG1
NAUT
CVBR
for
VB
= 4V
3.3μF
AUTARKY
BOOST
VCC2:
CFG2
R2
TOK
DETECT.
3.3V/2.5V/R3:R4
iC-DC
VCC2
R1
TEST
CONFIGURATION
I(VBR)
VCC1:= V (VB) ∗
CFG1
CFG2
R2
R4
THERMAL
TES
2
ENABLE
VCC2
R3
1
1.5...5.5V
CVCC2
R4
CONTROL
GNDA
It is possible
to use the
protective switch
at GND
pin VBR
SHUTDOWN
1μF
POE2
2
to provide
further ERROR
circuitry
withSUPPLY
protection against reDETECT.
2
LIN.-REG.2
SWITCH
2
verse polarity
(Figure 9, Page 17).
Here,
it must noted
VCC1,VCC2
BIAS capacity of the reverse polarthat the current
carrying
ity protection
(VBR)OSCILLATOR
is limited on1 startup.V1OK
As the device
RREF
powers
itself
from
VBR,
the
load
at
VBR
must
not be
REFERENCE
V2OK
RREF
SWITCHING
REGULATOR
2
too 20k
high as otherwise converter
operation
cannot
be
&
initiated. The
current
carrying
capacity
on
startup
can
ENV1
VOLTAGE by Equation 3:
OUTPUT
be approximately
described
MONITORING
ENV2
VCC1
2
1.5...5.5V
CVCC1
1μF
5V/3.3V/R1:R2
VCC2:
3.3V/2.5V/R3:R4
−1mA
V
(3)
iC-DC
GNDA GND
TES
iC-DC
preliminary
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 15/19
ERROR EVALUATION
Supply voltage monitor
Supply voltage VBR is monitored. If the normal voltage range is overshot or undershot, this is signaled at
open-drain pin VBROK. The bias current generated by
an external reference resistor is also monitored and an
error signaled at VBROK should the permissible range
be exceeded. If an error has occurred, pin VBROK is
switched to GND.
Output voltage monitor
The two linear regulator output voltages VCC1 and
VCC2 are also monitored. If the overvoltage threshold is overshot or the undervoltage threshold undershot (e.g. due to overload), a message is generated at
the current-limited push-pull outputs V1OK and V2OK.
Voltage outputs POE1 and POE2 are shut down.
Output voltage monitor self-test
Using pin TEST the voltage monitoring comparators at
V1OK and V2OK can be tested during ongoing operation. The undervoltage and overvoltage thresholds of
V1OK and V2OK are checked in turn with each test.
For this purpose, pin TEST is increased to above the
threshold voltage by an external driver. Correct functioning is signaled by low signals at pins V1OK and
V2OK. The function of the connected POE1 and POE2
outputs remains unaffected.
Temperature monitor
The internal chip temperature is monitored. If the
monitor indicates overtemperature, all switches on the
switching converter are shut down. These are automatically re-enabled when the chip temperature has
dropped below the restart temperature. A message is
signaled at open-drain pin TOK for as long as the converter is shut down due to chip overtemperature.
The protective switch (VB / VBR) has its own over
temperature protection, which is also operative during
standby mode.
As error outputs VBROK and TOK are current limited,
an LED can be directly connected up for visual message display. However, the additional power dissipation this causes in the IC must be taken into account.
By placing resistor RLED in series with the LED, this
additional chip power loss can be reduced in the event
of error. CMOS or TTL-compatible logic inputs can be
activated by pull-up resistors at VBROK and TOK.
AUTARKY FUNCTION
By inserting a capacitor at VBR, an Autarky function
can be realized should the supply fail at VB. This Autarky function guarantees the linear regulator output
voltages for some time. If the voltage at VBR is greater
than at VB (elec. char. no. 109), this is signaled by
current-limited open-drain output NAUT. To ensure that
VBR > VB should the supply voltage fail, it is recom-
mended that a resistor be switched between VB and
GND in order to generate the required differential voltage of dVBR, VB .
With this capacitor acting as a buffer, the effect of current spikes feeding back into the supply voltage VB is
also reduced.
iC-DC
preliminary
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 16/19
DESCRIPTION OF THE APPLICATION
Selecting the coil
The coil should be designed for a maximum cut-off
current of 1 A. A small internal resistor in the coil reduces loss and increases converter efficiency. At a low
supply voltage this internal resistor can determine the
maximum available output current.
The EMI caused by the coil should be taken into consideration. Toroidal core coils have little noise radiation yet are expensive and difficult to install. Bar core
coils are reasonably priced and easier to use yet have
a higher noise emittance. For modest EMI requirements inexpensive radio interference suppression coils
of several tens of µH are suitable∗ .
Selecting the capacitors
Selecting back-up capacitors CVH , CVH1 and CVH2 is
unproblematic. As the residual ripple of intermediate
voltages VH1 and VH2 does not affect output voltages VCC1 and VCC2 thanks to the back-end linear
regulators, a small capacitor is sufficient without any
specific demands being made of the internal resistor. A combination of electrolytic and ceramic capacitors (e.g. 3.3 µF || 100 nF) is recommended. Before using tantalum capacitors, the user must verify whether
these are suitable for the residual AC amplitude (residual ripple) at pins VH1 and VH2.
Printed circuit board layout
The GND path from the switching converter and from
each linear regulator should be strictly separated to
avoid cross couplings. The neutral point of all GND
paths is the GND connection at iC-DC. It is possible
and not critical, however, to route GND from supply VB
and the base point of capacitors CVH , CVH1 and CVH2
together to the neutral point. The capacitors should be
very close to their relevant pins, however.
Blocking capacitors for supply VB should be arranged
as close as possible to pins VB and GND. The capacitors for outputs VCC1 and VCC2 should be placed directly at the load and not at the IC to also block interferences which are coupled via the wiring to the load.
The ground planes underneath the wiring of output
voltages VCC1, VCC2, POE1, and POE2 should be
kept separate from the ground planes of switching converters VH, VH1, and VH2. The ground planes must
be connected up at a neutral point (see Figure 8).
The thermal pad should be connected to the PCB by
an appropriate ground plane. The resulting power dissipation can be transferred to a different wiring layer,
e.g. a ground plane, by vias directly underneath the
IC.
Stability of the linear regulators across the entire load
area is guaranteed if the values given in the electrical
characteristics are selected for CVCC1 and CVCC2.
The suppression of interference voltage is improved
by using small capacitor series resistors. A combination of tantalum and ceramic capacitors is also recommended in this case. If one of the two outputs remains
open, this capacitor can be omitted.
To avoid feedback of interference from supply voltage
VB onto output voltages VCC1 and VCC2, blocking
should be provided directly at pin VB. A combination
of tantalum and ceramic capacitors (e.g. 1 µF || 100 nF)
is also recommended in this case.
∗
Figure 8: Example layout: evaluation board DC1D
e.g.: Siemens Matsushita B78108-S1224-J (22 µH/1 A, axial), TDK series NLC565050T-. . . (SMD), TOKO series 10RF459-. . . (SMD
shielded)
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 17/19
EXAMPLE APPLICATION
VBR
VB
GND
4.5..32V
LVBH
D1 CVB
1μF
ZD1
0V
CVBR
10μF
22μH
VB
VBR
VBL
VHL
VH
CVH
3.3μF
REVERSE
PROTECT.
VCC1
VH1
CVH1
3.3μF
INTERNAL
SUPPLY
RERR
2k
NERR_DC
VCC1
VBROK
NAUT
TOK
BUCK
VOLTAGE
MONITOR
POE1
1
AUTARKY
DETECT.
BOOST
THERMAL
SHUTDOWN
1
SUPPLY
SWITCH 1
LIN.-REG.1
VH2
CONTROL
CVH2
3.3μF VCC2
ERROR DETECT.
VCC2
BIAS
RREF
RREF
20k
OSCILLATOR
SWITCHING REGULATOR
2
CVCC2
1μF
POE2
2
REFERENCE
VCC1
CVCC1
1μF
SUPPLY
SWITCH 2
LIN.-REG.2
VCC1,VCC2
VBR
ENV1
OUTPUT
ENABLE
CFG1
CONFIGURATION
VCC1:
5V/3.3V/R1:R2
VCC2:
3.3V/2.5V/R3:R4
VCC2 VCC1
R1
30.1k
V1OK
ENV2
CFG2
1
V2OK
2
&
iC-DC
R2
10k
VOLTAGE
MONITORING
TEST
GNDA GND
C1
100nF
SELECT RESOLUTION
C2
100nF
iC-LTA
iC-PT Series
TIP
TIN
SEL
PA
NA
PB
NB
PZ
LED
POWER
CONTROL
SIGNAL
COMPARATION
AND
QUADRATURE
OUTPUT
VCC
LED
PA
NA
PB
NERR_DC
MODE
ERROR DETECTION
iC-TL85
ENA
&
RLED
47
NB
E1
PZ
E2
UNDERVOLTAGE &
OVERTEMPERATURE
INDEX OUTPUT
A3
E5
+
V
E6
W
COMMUTATION
GND
GND1
GND2 GND3 GND4
VB2
D4
D10
A3
D11
A4
C5
100nF
D5
D12
A6
A5
0
DIFF
C4
100nF
VB3
1
W
A2
D3
VB3
A5
-
V
A1
D9
C3
100nF
A4
0
U
D8
VB2
0
E3
1
U
NER
VB1
D2
VB1
A2
E4
POWER-ON RESET
ZD2
A1
1
&
R3
NER
1
NZ
NZ
VCC
TNER
D6
iC-DL
D13
A6
D7
Figure 9: Application with iC-DC, iC-PT, and iC-DL
The application diagram in Figure 9 shows an example
circuit featuring the DC/DC converter iC-DC. The input
voltage range is set to between 4.5 V and 32 V by line
driver iC-DL. The output voltages of the two linear regulators are each configured to 5 V. VCC2 supplies the
optical 6-channel incremental scanner iC-LTA/iC-PT
and VCC1 the 5 V section of 24 V line driver iC-DL.
This creates a separation in the supply voltage between the sensing mechanism and the digital switching
section of the circuitry.
The status signals for overvoltage (VBROK) and
overtemperature (TOK) in iC-DC are connected to iCDL’s error message input TNER. This links the iC-
DC error messages to iC-DL’s own undervoltage and
overtemperature monitor. iC-DL’s open-drain error
message output NER thus provides the error messages for both ICs.
This example circuit makes use of iC-DC’s integrated
reverse polarity protection feature. The illustrated
diodes ZD1, ZD2, D2 to D13 and resistor R3 form the
basis for a protective circuit against overvoltage for all
outputs. No specific designations are given for these
components as these protective circuits are to be individually configured and dimensioned according to the
application and requirement.
preliminary
iC-DC
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 18/19
DESIGN REVIEW: Notes On Chip Functions
iC-DC Z
Nr.
Function, Parameter/Code
Description and Application Hints
1
Vc(VB)lo
Clamp Voltage lo at VB (elec. char. no. 013) can have a maximum of -40 V at low
temperature.
Table 6: Notes on chip functions regarding iC-DC chip release Z
iC-Haus expressly reserves the right to change its products and/or specifications. An info letter gives details as to any amendments and additions made to the
relevant current specifications on our internet website www.ichaus.de/infoletter; this letter is generated automatically and shall be sent to registered users by
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Copying – even as an excerpt – is only permitted with iC-Haus’ approval in writing and precise reference to source.
iC-Haus does not warrant the accuracy, completeness or timeliness of the specification and does not assume liability for any errors or omissions in these
materials.
The data specified is intended solely for the purpose of product description. No representations or warranties, either express or implied, of merchantability, fitness
for a particular purpose or of any other nature are made hereunder with respect to information/specification or the products to which information refers and no
guarantee with respect to compliance to the intended use is given. In particular, this also applies to the stated possible applications or areas of applications of
the product.
iC-Haus conveys no patent, copyright, mask work right or other trade mark right to this product. iC-Haus assumes no liability for any patent and/or other trade
mark rights of a third party resulting from processing or handling of the product and/or any other use of the product.
As a general rule our developments, IPs, principle circuitry and range of Integrated Circuits are suitable and specifically designed for appropriate use in technical
applications, such as in devices, systems and any kind of technical equipment, in so far as they do not infringe existing patent rights. In principle the range of
use is limitless in a technical sense and refers to the products listed in the inventory of goods compiled for the 2008 and following export trade statistics issued
annually by the Bureau of Statistics in Wiesbaden, for example, or to any product in the product catalogue published for the 2007 and following exhibitions in
Hanover (Hannover-Messe).
We understand suitable application of our published designs to be state-of-the-art technology which can no longer be classed as inventive under the stipulations
of patent law. Our explicit application notes are to be treated only as mere examples of the many possible and extremely advantageous uses our products can
be put to.
iC-DC
preliminary
2-CHANNEL BUCK/BOOST DC/DC CONVERTER
Rev A3, Page 19/19
ORDERING INFORMATION
Type
Package
Order Designation
iC-DC
QFN24 4 mm x 4 mm
iC-DC QFN24-4x4
Evaluation Board
iC-DC EVAL DC1D
For technical support, information about prices and terms of delivery please contact:
iC-Haus GmbH
Am Kuemmerling 18
D-55294 Bodenheim
GERMANY
Tel.: +49 (61 35) 92 92-0
Fax: +49 (61 35) 92 92-192
Web: http://www.ichaus.com
E-Mail: [email protected]
Appointed local distributors: http://www.ichaus.com/sales_partners