STMicroelectronics L7985 Voltage feed-forward Datasheet

L7985
2 A step-down switching regulator
Datasheet - production data
Applications
 Consumer: STB, DVD, DVD recorder, car
audio, LCD TV and monitors
 Industrial: PLD, PLA, FPGA, chargers
 Networking: XDSL, modems, DC-DC modules
VFQFPN10 3 x 3 mm
 Computer: optical storage, hard disk drive,
printers, audio/graphic cards
HSOP8 exp. pad
 LED driving
Features
Description
 2 A DC output current
The L7985/A is a step-down switching regulator
with a 2.5 A (minimum) current limited embedded
power MOSFET, so it is able to deliver up to 2 A
current to the load depending on the application
conditions. The input voltage can range from
4.5 V to 38 V, while the output voltage can be set
starting from 0.6 V to VIN. Requiring a minimum
set of external components, the device includes
an internal 250 kHz switching frequency oscillator
that can be externally adjusted up to 1 MHz. The
QFN and the HSOP packages with exposed pad
allow the reduction of RthJA down to 60 °C/W and
40 °C/W respectively.
 4.5 V to 38 V input voltage
 Output voltage adjustable from 0.6 V
 250 KHz switching frequency, programmable
up to 1 MHz
 Internal soft-start and enable
 Low dropout operation: 100% duty cycle
 Voltage feed-forward
 Zero load current operation
 Overcurrent and thermal protection
 VFQFPN 3 x 3 - 10L and HSOP8 package
Figure 1. Application circuit
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www.st.com
Contents
L7985
Contents
1
Pin settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.1
Pin connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.2
Pin description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2
Maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
3
Thermal data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
4
Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
5
Functional description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
6
7
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5.1
Oscillator and synchronization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
5.2
Soft-start . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11
5.3
Error amplifier and compensation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11
5.4
Overcurrent protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
5.5
Enable function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
5.6
Hysteretic thermal shutdown . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
6.1
Input capacitor selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
6.2
Inductor selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
6.3
Output capacitor selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
6.4
Compensation network . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
6.4.1
Type III compensation network . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
6.4.2
Type II compensation network . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
6.5
Thermal considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
6.6
Layout considerations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
6.7
Application circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
Application ideas . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.1
Positive buck-boost . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
7.2
Inverting buck-boost . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
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L7985
Contents
8
Package information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
9
Ordering information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40
10
Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
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Pin settings
L7985
1
Pin settings
1.1
Pin connection
Figure 2. Pin connection (top view)
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1.2
Pin description
Table 1. Pin description
No.
No.
(VFQFPN)
(HSOP)
1-2
1
OUT
3
2
SYNCH
4
3
EN
5
4
COMP
6
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Type
5
Description
Regulator output
Master/slave synchronization. When it is left floating,
a signal with a phase shift of half a period, with respect to the
power turn-on, is present at the pin. When connected to an
external signal at a frequency higher than the internal one,
the device is synchronized by the external signal, with zero
phase shift.
Connecting together the SYNCH pin of two devices, the one
with a higher frequency works as master and the other one
as slave; so the two power turn-ons have a phase shift of
half a period.
A logical signal (active high) enables the device. With EN
higher than 1.2 V the device is ON and with EN lower than
0.3 V the device is OFF.
Error amplifier output to be used for loop frequency
compensation.
FB
Feedback input. By connecting the output voltage directly to
this pin the output voltage is regulated at 0.6 V. To have
higher regulated voltages an external resistor divider is
required from VOUT to the FB pin.
7
6
FSW
The switching frequency can be increased connecting an
external resistor from the FSW pin and ground. If this pin is
left floating, the device works at its free-running frequency of
250 KHz.
8
7
GND
Ground
9 - 10
8
VCC
Unregulated DC input voltage.
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L7985
2
Maximum ratings
Maximum ratings
Table 2. Absolute maximum ratings
Symbol
Parameter
Vcc
Input voltage
OUT
Output DC voltage
Value
45
-0.3 to VCC
FSW, COMP, SYNCH Analog pin
3
-0.3 to 4
EN
Enable pin
-0.3 to VCC
FB
Feedback voltage
-0.3 to 1.5
PTOT
Unit
Power dissipation at TA < 60 °C
VFQFPN
1.5.
HSOP
2
V
W
TJ
Junction temperature range
-40 to 150
°C
Tstg
Storage temperature range
-55 to 150
°C
Value
Unit
Thermal data
Table 3. Thermal data
Symbol
RthJA
Parameter
Maximum thermal resistance
junction ambient(1)
VFQFPN
60
HSOP
40
°C/W
1. Package mounted on demonstration board.
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Electrical characteristics
4
L7985
Electrical characteristics
TJ = 25 °C, VCC = 12 V, unless otherwise specified.
Table 4. Electrical characteristics
Values
Symbol
Parameter
Test conditions
Unit
Min.
Operating input voltage range
(1)
Turn on VCC threshold
(1)
VCCHYS
VCC UVLO hysteseris
(1)
RDSON
MOSFET on resistance
VCC
VCCON
ILIM
Typ.
4.5
Max.
38
4.5
0.1
0.4
200
(1)
Maximum limiting current
V
400
m
2.5
3.0
3.5
A
210
250
275
KHz
Oscillator
FSW
Switching frequency
VFSW
FSW pin voltage
D
FADJ
(1)
1.254
Duty cycle
Adjustable switching frequency
0
RFSW = 33 k
V
100
1000
%
KHz
Dynamic characteristics
VFB
Feedback voltage
4.5 V < VCC < 38 V
0.593
0.6
0.607
4.5 V < VCC < 38 V(1)
0.582
0.6
0.618
V
DC characteristics
IQ
IQST-BY
Quiescent current
Duty cycle = 0, VFB = 0.8 V
Total standby quiescent current
20
2.4
mA
30
A
Enable
VEN
EN threshold voltage
IEN
EN current
Device OFF level
Device ON level
0.3
1.2
EN = VCC
7.5
10
8.2
9.1
V
A
Soft-start
TSS
Soft-start duration
FSW pin floating
7.4
FSW = 1 MHz, R FSW = 33 k
2
ms
Error amplifier
VCH
High level output voltage
VFB < 0.6 V
VCL
Low level output voltage
VFB > 0.6 V
Source COMP pin
VFB = 0.5 V, VCOMP = 1 V
IO SOURCE
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0.1
19
V
mA
L7985
Electrical characteristics
Table 4. Electrical characteristics (continued)
Values
Symbol
Parameter
Test conditions
Unit
Min.
IO SINK
GV
Sink COMP pin
VFB = 0.7 V, VCOMP = 1 V
Open-loop voltage gain
(2)
Typ.
Max.
30
mA
100
dB
Synchronization function
VS_IN,HI
High input voltage
2
VS_IN,LO
Low input voltage
tS_IN_PW
Input pulse width
ISYNCH,LO
Slave sink current
VSYNCH = 2.9 V
VS_OUT,HI
Master output amplitude
ISOURCE = 4.5 mA
tS_OUT_PW
Output pulse width
SYNCH floating
3.3
1
VS_IN,HI = 3 V, VS_IN,LO = 0 V
100
VS_IN,HI = 2 V, VS_IN,LO = 1 V
300
V
ns
0.7
1
2
mA
V
110
ns
Protection
TSHDN
Thermal shutdown
150
Hystereris
30
°C
1. Specifications referred to TJ from -40 to +125 °C. Specifications in the -40 to +125 °C temperature range are assured by
design, characterization and statistical correlation.
2. Guaranteed by design.
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Functional description
5
L7985
Functional description
The L7985 device is based on a “voltage mode” constant frequency control. The output
voltage VOUT is sensed by the feedback pin (FB) compared to an internal reference (0.6 V)
providing an error signal that, compared to a fixed frequency sawtooth, controls the on- and
off-time of the power switch.
The main internal blocks are shown in the block diagram in Figure 3. They are:

A fully integrated oscillator that provides sawtooth to modulate the duty cycle and the
synchronization signal. Its switching frequency can be adjusted by an external resistor.
The voltage and frequency feed-forward are implemented.

The soft-start circuitry to limit inrush current during the startup phase.

The voltage mode error amplifier.

The pulse width modulator and the relative logic circuitry necessary to drive the internal
power switch.

The high-side driver for embedded P-channel power MOSFET switch.

The peak current limit sensing block, to handle overload and short-circuit conditions.

A voltage regulator and internal reference. To supply the internal circuitry and provide
a fixed internal reference.

A voltage monitor circuitry (UVLO) that checks the input and internal voltages.

A thermal shutdown block, to prevent thermal runaway.
Figure 3. Block diagram
VCC
REGULATOR
TRIMMING
EN
&
BANDGAP
EN
1.254V
3.3V
0.6V
COMP
UVLO
PEAK
CURRENT
LIMIT
THERMAL
SOFTSTART
SHUTDOWN
E/A
PWM
DRIVER
S
Q
R
OUT
OSCILLATOR
FB
8/42
FSW
GND
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SYNCH
&
PHASE SHIFT
SYNCH
L7985
5.1
Functional description
Oscillator and synchronization
Figure 4 shows the block diagram of the oscillator circuit. The internal oscillator provides
a constant frequency clock. Its frequency depends on the resistor externally connect to the
FSW pin. If the FSW pin is left floating, the frequency is 250 kHz; it can be increased as
shown in Figure 6 by an external resistor connected to ground.
To improve the line transient performance, keeping the PWM gain constant versus the input
voltage, the voltage feed-forward is implemented by changing the slope of the sawtooth
according to the input voltage change (see Figure 5.a).
The slope of the sawtooth also changes if the oscillator frequency is increased by the
external resistor. In this way a frequency feed-forward is implemented (Figure 5.b) in order
to keep the PWM gain constant versus the switching frequency (see Section 6.4 on page 18
for PWM gain expression).
On the SYNCH pin the synchronization signal is generated. This signal has a phase shift of
180 ° with respect to the clock. This delay is useful when two devices are synchronized
connecting the SYNCH pin together. When the SYNCH pins are connected, the device with
a higher oscillator frequency typically works as the master, so the slave device switches at
the frequency of the master but with a delay of half a period. This minimizes the RMS
current flowing through the input capacitor (see the L5988D datasheet).
The SYNCH circuitry is also able to synchronize with a slightly lower external frequency, so
the frequency pre-adjustment with the same resistor on the FSW pin, as described below, is
suggested for a proper operation.
Figure 4. Oscillator circuit block diagram
Clock
FSW
Clock
Generator
Synchronization
SYNCH
Ramp
Generator
Sawtooth
The device can be synchronized to work at higher frequency feeding an external clock
signal. The synchronization changes the sawtooth amplitude, changing the PWM gain
(Figure 5.c). This change has to be taken into account when the loop stability is studied. To
minimize the change of PWM gain, the free-running frequency should be set (with a resistor
on the FSW pin) only slightly lower than the external clock frequency. This pre-adjusting of
the frequency changes the sawtooth slope in order to render the truncation of sawtooth
negligible, due to the external synchronization.
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Functional description
L7985
Figure 5. Sawtooth: voltage and frequency feed-forward; external synchronization
Figure 6. Oscillator frequency vs. FSW pin resistor
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L7985
5.2
Functional description
Soft-start
The soft-start is essential to assure correct and safe startup of the step-down converter. It
avoids inrush current surge and makes the output voltage increase monothonically.
The soft-start is performed by a staircase ramp on the non-inverting input (VREF) of the error
amplifier. So the output voltage slew rate is:
Equation 1
R1
SR OUT = SR VREF   1 + --------

R2
where SRVREF is the slew rate of the non-inverting input, while R1and R2 is the resistor
divider to regulate the output voltage (see Figure 7). The soft-start staircase consists of 64
steps of 9.5 mV each, from 0 V to 0.6 V. The time base of one step is of 32 clock cycles. So
the soft-start time and then the output voltage slew rate depend on the switching frequency.
Figure 7. Soft-start scheme
Soft-start time results:
Equation 2
32  64
SS TIME = ----------------Fsw
For example, with a switching frequency of 250 kHz, the SSTIME is 8 ms.
5.3
Error amplifier and compensation
The error amplifier (E/A) provides the error signal to be compared with the sawtooth to
perform the pulse width modulation. Its non-inverting input is internally connected to a 0.6 V
voltage reference, while its inverting input (FB) and output (COMP) are externally available
for feedback and frequency compensation. In this device the error amplifier is a voltage
mode operational amplifier, therefore, with high DC gain and low output impedance.
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Functional description
L7985
The uncompensated error amplifier characteristics are the following:
Table 5. Uncompensated error amplifier characteristics
Parameter
Value
Low frequency gain
100 dB
GBWP
4.5 MHz
Slew rate
7 V/s
Output voltage swing
0 to 3.3 V
Maximum source/sink current
17 mA/25 mA
In continuous conduction mode (CCM), the transfer function of the power section has two
poles due to the LC filter and one zero due to the ESR of the output capacitor. Different
kinds of compensation networks can be used depending on the ESR value of the output
capacitor. If the zero introduced by the output capacitor helps to compensate the double
pole of the LC filter, a type II compensation network can be used. Otherwise, a type III
compensation network must be used (see Section 6.4 on page 18 for details of the
compensation network selection).
Anyway, the methodology to compensate the loop is to introduce zeroes to obtain a safe
phase margin.
5.4
Overcurrent protection
The L7985 implements overcurrent protection by sensing current flowing through the power
MOSFET. Due to the noise created by the switching activity of the power MOSFET, the
current sensing is disabled during the initial phase of the conduction time. This avoids an
erroneous detection of a fault condition. This interval is generally known as “masking time”
or “blanking time”. The masking time is about 200 ns.
If the overcurrent limit is reached, the power MOSFET is turned off, implementing pulse-bypulse overcurrent protection. In the overcurrent condition, the device can skip turn-on pulses
in order to keep the output current constant and equal to the current limit. If, at the end of the
“masking time”, the current is higher than the overcurrent threshold, the power MOSFET is
turned off and one pulse is skipped. If, at the following switching on, when the “masking
time” ends, the current is still higher than the overcurrent threshold, the device skips two
pulses. This mechanism is repeated and the device can skip up to seven pulses. While, if at
the end of the “masking time”, the current is lower than the overcurrent threshold, the
number of skipped cycles is decreased by one unit (see Figure 8).
So, the overcurrent/short-circuit protection acts by switching off the power MOSFET and
reducing the switching frequency down to one eighth of the default switching frequency, in
order to keep constant the output current around the current limit.
This kind of overcurrent protection is effective if the output current is limited. To prevent the
current from diverging, the current ripple in the inductor during the on-time must not be
higher than the current ripple during the off-time. That is:
Equation 3
V IN – V OUT – R DSON  I OUT – DCR  I OUT
V OUT + V F + R DSON  I OUT + DCR  I OUT
------------------------------------------------------------------------------------------------------------  D = -----------------------------------------------------------------------------------------------------------   1 – D 
L  F SW
L  F SW
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L7985
Functional description
If the output voltage is shorted, VOUT 0, IOUT = ILIM, D/FSW = TON_MIN, (1 - D)/FSW 1/FSW.
So, from Equation 3, the maximum switching frequency that guarantees to limit the current
results:
Equation 4
 V F + DCR  I LIM 
1
F *SW = -------------------------------------------------------------------------------  --------------------- V IN –  R DSON + DCR   I LIM  T ON_MIN
With RDSON = 300 m, DCR = 0.08 , the worst condition is with VIN = 38 V, ILIM = 2.5 A; the
maximum frequency to keep the output current limited during the short-circuit results
74 kHz.
The pulse-by-pulse mechanism, which reduces the switching frequency down to one eighth
of the maximum FSW, adjusted by the FSW pin, assures that a full effective output current
limitation is 74 kHz * 8 = 592 kHz.
If, with VIN = 38 V, the switching frequency is set higher than 592 kHz, during short-circuit
condition the system finds a different equilibrium with higher current. For example, with
FSW = 700 kHz and the output shorted to ground, the output current is limited around:
Equation 5
V IN  F *SW – V F  T ON_MIN
I OUT = ---------------------------------------------------------------------------------------------------------------- = 3.68A
 DRC  T ON_MIN  +  R DSON + DCR   F *SW
where FSW* is 700 kHz divided by eight.
Figure 8. Overcurrent protection
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Functional description
5.5
L7985
Enable function
The enable feature allows to put the device into standby mode. With the EN pin lower than
0.3 V the device is disabled and the power consumption is reduced to less than 30 µA. With
the EN pin lower than 1.2 V, the device is enabled. If the EN pin is left floating, an internal
pull-down ensures that the voltage at the pin reaches the inhibit threshold and the device is
disabled. The pin is also VCC compatible.
5.6
Hysteretic thermal shutdown
The thermal shutdown block generates a signal that turns off the power stage if the junction
temperature goes above 150 °C. Once the junction temperature returns to about 120 °C, the
device restarts in normal operation. The sensing element is very close to the PDMOS area,
so ensuring an accurate and fast temperature detection.
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L7985
Application information
6
Application information
6.1
Input capacitor selection
The capacitor connected to the input must be capable of supporting the maximum input
operating voltage and the maximum RMS input current required by the device. The input
capacitor is subject to a pulsed current, the RMS value of which is dissipated over its ESR,
affecting the overall system efficiency.
So, the input capacitor must have an RMS current rating higher than the maximum RMS
input current and an ESR value compliant with the expected efficiency.
The maximum RMS input current flowing through the capacitor can be calculated as:
Equation 6
2
2
2D
D
I RMS = I O  D – --------------- + ------2

where IO is the maximum DC output current, D is the duty cycle, is the efficiency.
Considering , this function has a maximum of D = 0.5 and it is equal to IO/2.
In a specific application, the range of possible duty cycles must be considered in order to
find out the maximum RMS input current. The maximum and minimum duty cycles can be
calculated as:
Equation 7
V OUT + V F
D MAX = ------------------------------------V INMIN – V SW
and
Equation 8
V OUT + V F
D MIN = -------------------------------------V INMAX – V SW
where VF is the forward voltage on the freewheeling diode and VSW is the voltage drop
across the internal PDMOS.
The peak-to-peak voltage across the input capacitor can be calculated as:
Equation 9
IO
D
D
V PP = -------------------------   1 – ----  D + ----   1 – D  + ESR  I O
C IN  F SW 


where ESR is the equivalent series resistance of the capacitor.
Given the physical dimension, ceramic capacitors can well meet the requirements of the
input filter sustaining a higher input RMS current than electrolytic/tantalum types. In this
case the equation of CIN as a function of the target VPP can be written as follows:
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Application information
L7985
Equation 10
IO
D
D
C IN = ---------------------------   1 – ----  D + ----   1 – D 
V PP  F SW 


neglecting the small ESR of the ceramic capacitors.
Considering = 1, this function has its maximum in D = 0.5, therefore, given the maximum
peak-to-peak input voltage (VPP_MAX), the minimum input capacitor (CIN_MIN) value is:
Equation 11
IO
C IN_MIN = -----------------------------------------------2  V PP_MAX  F SW
Typically CIN is dimensioned to keep the maximum peak-peak voltage in the order of 1% of
VINMAX.
In Table 6 some multi-layer ceramic capacitors suitable for this device are reported.
Table 6. Input MLC capacitors
Manufacture
Taiyo Yuden
Murata
Series
Cap value (F)
Rated voltage (V)
UMK325BJ106MM-T
10
50
GMK325BJ106MN-T
10
35
GRM32ER71H475K
4.7
50
A ceramic bypass capacitor, as close to the VCC and GND pins as possible, so that
additional parasitic ESR and ESL are minimized, is suggested in order to prevent instability
on the output voltage due to noise. The value of the bypass capacitor can go from 100 nF to
1 µF.
6.2
Inductor selection
The inductance value fixes the current ripple flowing through the output capacitor. So the
minimum inductance value, in order to have the expected current ripple, must be selected.
The rule to fix the current ripple value is to have a ripple at 20% - 40% of the output current.
In continuous current mode (CCM), the inductance value can be calculated by the following
equation:
Equation 12
V IN – V OUT
V OUT + V F
I L = ------------------------------  T ON = ----------------------------  T OFF
L
L
where TON is the conduction time of the internal high-side switch and TOFF is the conduction
time of the external diode [in CCM, FSW = 1 / (TON + TOFF)]. The maximum current ripple, at
fixed VOUT, is obtained at maximum TOFF which is at minimum duty cycle (see Section 6.1 to
calculate minimum duty). So, by fixing IL = 20% to 30% of the maximum output current, the
minimum inductance value can be calculated:
16/42
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L7985
Application information
Equation 13
V OUT + V F 1 – D MIN
L MIN = ----------------------------  ----------------------I MAX
F SW
where FSW is the switching frequency, 1 / (TON + TOFF).
For example, for VOUT = 5 V, VIN = 24 V, IO = 2 A and FSW = 250 kHz, the minimum
inductance value to have IL = 30% of IO is about 28 H.
The peak current through the inductor is given by:
Equation 14
I L
I L PK = I O + -------2
So, if the inductor value decreases, then the peak current (that must be lower than the
minimum current limit of the device) increases. According to the maximum DC output
current for this product family (2 A), the higher the inductor value, the higher the average
output current that can be delivered, without triggering the overcurrent protection.
In Table 7 some inductor part numbers are listed.
Table 7. Inductors
Manufacturer
Coilcraft
Wurth
SUMIDA
6.3
Series
Inductor value (H)
Saturation current (A)
MSS1038
3.8 to 10
3.9 to 6.5
MSS1048
12 to 22
3.84 to 5.34
PD Type L
8.2 to 15
3.75 to 6.25
PD Type M
2.2 to 4.7
4 to 6
CDRH6D226/HP
1.5 to 3.3
3.6 to 5.2
CDR10D48MN
6.6 to 12
4.1 to 5.7
Output capacitor selection
The current in the capacitor has a triangular waveform which generates a voltage ripple
across it. This ripple is due to the capacitive component (charge or discharge of the output
capacitor) and the resistive component (due to the voltage drop across its ESR). So the
output capacitor must be selected in order to have a voltage ripple compliant with the
application requirements.
The amount of the voltage ripple can be calculated starting from the current ripple obtained
by the inductor selection.
Equation 15
I MAX
V OUT = ESR  I MAX + ------------------------------------8  C OUT  f SW
Usually the resistive component of the ripple is much higher than the capacitive one, if the
output capacitor adopted is not a multi-layer ceramic capacitor (MLCC) with very low ESR
value.
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42
Application information
L7985
The output capacitor is important also for loop stability: it fixes the double LC filter pole and
the zero due to its ESR. Section 6.4 illustrates how to consider its effect in the system
stability.
For example, with VOUT = 5 V, VIN = 24 V, IL = 0.6 A (resulting by the inductor value), in
order to have a VOUT = 0.01·VOUT, if the multi-layer ceramic capacitors are adopted, 10 µF
are needed and the ESR effect on the output voltage ripple can be neglected. In the case of
non-negligible ESR (electrolytic or tantalum capacitors), the capacitor is chosen taking into
account its ESR value. So, in the case of 330 µF with ESR = 70 m, the resistive
component of the drop dominates and the voltage ripple is 43 mV
The output capacitor is also important to sustain the output voltage when a load transient
with high slew rate is required by the load. When the load transient slew rate exceeds the
system bandwidth, the output capacitor provides the current to the load. So, if the high slew
rate load transient is required by the application, the output capacitor and system bandwidth
must be chosen in order to sustain the load transient.
In Table 8 some capacitor series are listed.
Table 8. Output capacitors
Manufacturer
Series
Cap value (F)
Rated voltage (V)
ESR (m)
GRM32
22 to 100
6.3 to 25
<5
GRM31
10 to 47
6.3 to 25
<5
ECJ
10 to 22
6.3
<5
EEFCD
10 to 68
6.3
15 to 55
SANYO
TPA/B/C
100 to 470
4 to 16
40 to 80
TDK
C3225
22 to 100
6.3
<5
MURATA
PANASONIC
6.4
Compensation network
The compensation network must assure stability and good dynamic performance. The loop
of the L7985 is based on the voltage mode control. The error amplifier is a voltage
operational amplifier with high bandwidth. So, by selecting the compensation network, the
E/A is considered as ideal, that is, its bandwidth is much larger than the system one.
The transfer functions of the PWM modulator and the output LC filter are studied (see
Figure 9). The transfer function of the PWM modulator, from the error amplifier output
(COMP pin) to the OUT pin, results:
Equation 16
V IN
G PW0 = --------Vs
where VS is the sawtooth amplitude. As seen in Section 5.1 on page 9, the voltage feedforward generates a sawtooth amplitude directly proportional to the input voltage, that is:
Equation 17
V S = K  V IN
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L7985
Application information
In this way the PWM modulator gain results constant and equal to:
Equation 18
V IN
1
G PW0 = --------- = ---- = 18
Vs
K
The synchronization of the device with an external clock provided through the SYNCH pin
can modify the PWM modulator gain (see Section 5.1 on page 9 to understand how this gain
changes and how to keep it constant in spite of the external synchronization).
Figure 9. The error amplifier, the PWM modulator, and the LC output filter
VCC
VS
VREF
FB
PWM
E/A
OUT
COMP
L
ESR
GPW0
GLC
COUT
The transfer function on the LC filter is given by:
Equation 19
s
1 + -------------------------2  f zESR
G LC  s  = ------------------------------------------------------------------------2s
s
1 + ---------------------------- +  -------------------
2  Q  f LC  2  f LC
where:
Equation 20
1
f LC = ------------------------------------------------------------------------
ESR
2  L  C OUT  1 + --------------R OUT
1
f zESR = -------------------------------------------2  ESR  C OUT
Equation 21
R OUT  L  C OUT   R OUT + ESR 
Q = ------------------------------------------------------------------------------------------ ,
L + C OUT  R OUT  E SR
DocID022446 Rev 7
V OUT
R OUT = -------------I OUT
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Application information
L7985
As seen in Section 5.3 on page 11, two different kinds of network can compensate the loop.
In the following two paragraphs the guidelines to select the type II and type III compensation
network are illustrated.
6.4.1
Type III compensation network
The methodology to stabilize the loop consists of placing two zeroes to compensate the
effect of the LC double pole, therefore increasing phase margin; then, to place one pole in
the origin to minimize the DC error on regulated output voltage; and finally, to place other
poles far from the zero dB frequency.
If the equivalent series resistance (ESR) of the output capacitor introduces a zero with
a frequency higher than the desired bandwidth (that is: 2ESR COUT < 1 / BW), the type
III compensation network is needed. Multi-layer ceramic capacitors (MLCC) have very low
ESR (< 1 m), with very high frequency zero, so a type III network is adopted to
compensate the loop.
In Figure 10 the type III compensation network is shown. This network introduces two
zeroes (fZ1, fZ2) and three poles (fP0, fP1, fP2). They are expressed as:
Equation 22
1
f Z1 = ------------------------------------------------
2  C 3   R 1 + R 3 
1
f Z2 = -----------------------------2  R 4  C 4
Equation 23
f P0 = 0
1
f P1 = ------------------------------
2  R 3  C 3
1
f P2 = -------------------------------------------C4  C5
2  R 4  -------------------C4 + C5
Figure 10. Type III compensation network
In Figure 11 the Bode diagram of the PWM and LC filter transfer function (GPW0 · GLC(f))
and the open-loop gain (GLOOP(f) = GPW0 · GLC(f) · GTYPEIII(f)) are shown.
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Application information
Figure 11. Open-loop gain: module Bode diagram
The guidelines for positioning the poles and the zeroes and for calculating the component
values can be summarized as follows:
1.
Choose a value for R1, usually between 1 k and 5 k.
2.
Choose a gain (R4/R1) in order to have the required bandwidth (BW), that means:
Equation 24
BW
R 4 = ----------  K  R 1
f LC
where K is the feed-forward constant and 1/K is equal to 18.
3.
Calculate C4 by placing the zero at 50% of the output filter double pole frequency (fLC):
Equation 25
1
C 4 = --------------------------  R 4  f LC
4.
Calculate C5 by placing the second pole at four times the system bandwidth (BW):
Equation 26
C4
C 5 = -------------------------------------------------------------2  R 4  C 4  4  BW – 1
5.
Set also the first pole at four times the system bandwidth and also the second zero at
the output filter double pole:
Equation 27
R1
R 3 = ---------------------------
4  BW
----------------- – 1
f LC
1
C 3 = ----------------------------------------2  R 3  4  BW
The suggested maximum system bandwidth is equal to the switching frequency divided by
3.5 (FSW / 3.5), anyhow, lower than 100 kHz if the FSW is set higher than 500 kHz.
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L7985
For example, with VOUT = 5 V, VIN = 24 V, IO = 2 A, L = 22 H, COUT = 22 F, and
ESR < 1 m, the type III compensation network is:
R 1 = 4.99k
R 2 = 680 R 3 = 270 R 4 = 1.1k
C 3 = 4.7nF
C 4 = 47nF
C 5 = 1nF
In Figure 12 the module and phase of the open-loop gain is shown. The bandwidth is about
32 kHz and the phase margin is 51 °.
Figure 12. Open-loop gain Bode diagram with ceramic output capacitor
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L7985
6.4.2
Application information
Type II compensation network
If the equivalent series resistance (ESR) of the output capacitor introduces a zero with
a frequency lower than the desired bandwidth (that is: 2ESR COUT > 1 / BW), this zero
helps stabilize the loop. Electrolytic capacitors show non-negligible ESR (> 30 m), so with
this kind of output capacitor the type II network combined with the zero of the ESR allows
the stabilization of the loop.
In Figure 13 the type II network is shown.
Figure 13. Type II compensation network
The singularities of the network are:
Equation 28
1
f Z1 = ------------------------------
2  R 4  C 4
f P0 = 0
DocID022446 Rev 7
1
f P1 = -------------------------------------------C4  C5
2  R 4  -------------------C4 + C5
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Application information
L7985
In Figure 14 the Bode diagram of the PWM and LC filter transfer function (GPW0 · GLC(f))
and the open-loop gain (GLOOP(f) = GPW0 · GLC(f) · GTYPEII(f)) are shown.
Figure 14. Open-loop gain: module Bode diagram
The guidelines for positioning the poles and the zeroes and for calculating the component
values can be summarized as follows:
1.
Choose a value for R1, usually between 1 k and 5 k, in order to have values of C4
and C5 not comparable with parasitic capacitance of the board.
2.
Choose a gain (R4/R1) in order to have the required bandwidth (BW), that means:
Equation 29
f ESR 2 BW V S
R 4 =  ------------  ------------  ---------  R 1
f LC
f ESR V IN
where fESR is the ESR zero:
Equation 30
1
f ESR = -------------------------------------------2  ESR  C OUT
and VS is the sawtooth amplitude. The voltage feed-forward keeps the ratio VS/VIN constant.
3.
Calculate C4 by placing the zero one decade below the output filter double pole:
Equation 31
10
C 4 = ------------------------------2  R 4  f LC
4.
24/42
Then calculate C3 in order to place the second pole at four times the system bandwidth
(BW):
DocID022446 Rev 7
L7985
Application information
Equation 32
C4
C 5 = -------------------------------------------------------------2  R 4  C 4  4  BW – 1
For example with VOUT = 5 V, VIN = 24 V, IO = 2 A, L = 22 H, COUT = 330 F, ESR = 70 m
the type II compensation network is:
R 1 = 1.1k
R 2 = 150
R 4 = 4.99k
C 4 = 180nF
C 5 = 180pF
In Figure 15 the module and phase of the open-loop gain is shown. The bandwidth is about
36 kHz and the phase margin is 53 °.
Figure 15. Open-loop gain Bode diagram with electrolytic/tantalum output capacitor
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42
Application information
6.5
L7985
Thermal considerations
The thermal design is important to prevent the thermal shutdown of the device if junction
temperature goes above 150 °C. The three different sources of losses within the device are:
a)
conduction losses due to the non-negligible RDSON of the power switch; these are
equal to:
Equation 33
2
P ON = R DSON   I OUT   D
where D is the duty cycle of the application and the maximum RDSON overtemperature is
220 m. Note that the duty cycle is theoretically given by the ratio between VOUT and VIN,
but actually it is quite higher to compensate the losses of the regulator. So the conduction
losses increase compared with the ideal case.
b)
switching losses due to power MOSFET turn ON and OFF; these can be
calculated as:
Equation 34
 T RISE + T FALL 
P SW = V IN  I OUT  -------------------------------------------  Fsw = V IN  I OUT  T SW  F SW
2
where TRISE and TFALL are the overlap times of the voltage across the power switch (VDS)
and the current flowing into it during turn ON and turn OFF phases, as shown in Figure 16.
TSW is the equivalent switching time. For this device the typical value for the equivalent
switching time is 40 ns.
c)
Quiescent current losses, calculated as:
Equation 35
P Q = V IN  I Q
where IQ is the quiescent current (IQ = 2.4 mA).
The junction temperature TJ can be calculated as:
Equation 36
T J = T A + Rth JA  P TOT
where TA is the ambient temperature and PTOT is the sum of the power losses just seen.
RthJA is the equivalent thermal resistance junction to ambient of the device; it can be
calculated as the parallel of many paths of heat conduction from the junction to the ambient.
For this device the path through the exposed pad is the one conducting the largest amount
of heat. The RthJA, measured on the demonstration board described in the following
paragraph, is about 60 °C/W for the VFQFPN package and about 40 °C/W for the HSOP
package.
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L7985
Application information
Figure 16. Switching losses
6.6
Layout considerations
The PC board layout of the switching DC/DC regulator is very important to minimize the
noise injected in high impedance nodes and interference generated by the high switching
current loops.
In a step-down converter, the input loop (including the input capacitor, the power MOSFET
and the freewheeling diode) is the most critical one. This is due to the fact that the high
value pulsed currents are flowing through it. In order to minimize the EMI, this loop must be
as short as possible.
The feedback pin (FB) connection to the external resistor divider is a high impedance node,
so the interference can be minimized by placing the routing of the feedback node as far as
possible from the high current paths. To reduce the pick-up noise, the resistor divider must
be placed very close to the device.
To filter the high frequency noise, a small bypass capacitor (220 nF - 1 µF) can be added as
close as possible to the input voltage pin of the device.
Thanks to the exposed pad of the device, the ground plane helps to reduce the thermal
resistance junction to ambient; so a large ground plane enhances the thermal performance
of the converter allowing high power conversion.
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42
Application information
L7985
In Figure 17 a layout example is shown.
Figure 17. Layout example
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L7985
6.7
Application information
Application circuit
In Figure 18 the demonstration board application circuit is shown.
Figure 18. Demonstration board application circuit
Table 9. Component list
Reference
Part number
Description
Manufacturer
C1
UMK325BJ106MM-T
10 F, 50 V
Taiyo Yuden
C2
GRM32ER61E226KE15
22 F, 25 V
Murata
C3
3.3 nF, 50 V
C4
33 nF, 50 V
C5
100 pF, 50 V
C6
470 nF, 50 V
R1
4.99 k, 1%, 0.1 W 0603
R2
1.1 k, 1%, 0.1 W 0603
R3
330 , 1%, 0.1 W 0603
R4
1.5 k, 1%, 0.1 W 0603
R5
150 k1%, 0.1 W 0603
D1
STPS3L40
3A DC, 40 V
STMicroelectronics
L1
MSS1038-103NL
10 H, 30%, 3.9 A,
DCRMAX=35 m
Coilcraft
DocID022446 Rev 7
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42
Application information
L7985
Figure 19. PCB layout: L7985 and L7985A (component side)
Figure 20. PCB layout: L7985 and L7985A (bottom side)
Figure 21. PCB layout: L7985 and L7985A (front side)
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L7985
Application information
Figure 22. Junction temperature vs. output
current VIN = 24 V
VQFN
Figure 23. Junction temperature vs. output
current VIN = 12 V
VQFN
HSOP
VOUT=5V
VOUT=5V
VOUT=3.3V
VOUT=3.3V
VOUT=1.8V
VOUT=1.8V
HSOP
VIN=24V
FSW=250KHz
TAMB=25 C
VIN=24V
FSW=250KHz
TAMB=25 C
Figure 24. Junction temperature vs. output
current VIN = 5 V
Figure 25. Efficiency vs. output current
VO = 1.8 V
85
VQFN
Vo=1.8V
FSW=250kHz
80
HSOP
75
VOUT=1.8V
70
VOUT=1.2V
65
Eff [%]
VOUT=3.3V
60
55
VIN=5V
FSW=250KHz
TAMB=25 C
50
Vin=5V
Vin=12V
45
40
0.100
Vin=24V
0.600
1.100
1.600
2.100
Io [A]
Figure 26. Efficiency vs.output current
VO = 5.0 V
Figure 27. Efficiency vs. output current
VO = 3.3 V
95
95
Vo=5.0V
FSW=250kHz
Vo=3.3V
FSW=250kHz
90
90
85
80
80
Eff [%]
Eff [%]
85
75
70
65
70
Vin=12V
Vin=18V
65
60
0.100
75
Vin=24V
0.600
1.100
1.600
2.100
60
Vin=5V
Vin=12V
55
50
0.100
Vin=24V
0.600
1.100
1.600
2.100
Io [A]
Io [A]
DocID022446 Rev 7
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42
Application information
L7985
Figure 28. Load regulation
Figure 29. Line regulation
3.345
3.3500
Vin=5V
3.340
Io=1A
Vin=12V
3.3450
Vin=24V
Io=2A
3.3400
3.330
VOUT [V]
VOUT [V]
3.335
3.325
3.3350
3.3300
3.320
3.3250
3.315
3.310
0.00
3.3200
0.50
1.00
1.50
5.0
2.00
10.0
15.0
20.0
25.0
Figure 30. Load transient: from 0.4 A to 2 A
35.0
40.0
Figure 31. Soft-start
VOUT
100mV/div
AC coupled
VOUT
500mV/div
IL
500mA/div
VIN=24V
VOUT=3.3V
COUT=47uF
L=10uH
FSW=520k
IL 500mA/div
30.0
VIN [V]
Io [A]
VFB
200mV/div
Time base 1ms/div
Time base 100us/div
Figure 32. Short-circuit behavior VIN = 12 V
SYNCH
Figure 33. Short-circuit behavior VIN = 24 V
SYNCH
5V/div
5V/div
OUT
OUT
5V/div
5V/div
VOUT
VOUT
1V/div
1V/div
IL
IL
0.5A/div
1A/div
Timebase 10us/div
32/42
DocID022446 Rev 7
Timebase 10us/div
L7985
Application ideas
7
Application ideas
7.1
Positive buck-boost
The L7985 can implement the step-up/down converter with a positive output voltage.
Figure 34 shows the schematic: one power MOSFET and one Schottky diode are added to
the standard buck topology to provide a 12 V output voltage with input voltage from 4.5 V to
38 V.
Figure 34. Positive buck-boost regulator
5
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6736/8
9287
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(1
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'
6736/8
&
—)
5
5
73
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5
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6711)/
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5
*1'
$0
The relationship between input and output voltage is:
Equation 37
D
V OUT = V IN  ------------1–D
so the duty cycle is:
Equation 38
V OUT
D = -----------------------------V OUT + V IN
The output voltage isn’t limited by the maximum operating voltage of the device (38 V),
because the output voltage is sensed only through the resistor divider. The external power
MOSFET maximum drain to source voltage, must be higher than output voltage; the
maximum gate to source voltage must be higher than the input voltage (in Figure 34, if VIN is
higher than 16 V, the gate must be protected through Zener diode and resistor).
The current flowing through the internal power MOSFET is transferred to the load only
during the off-time, so according to the maximum DC switch current (2.0 A), the maximum
output current for the buck-boost topology can be calculated from Equation 39.
DocID022446 Rev 7
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42
Application ideas
L7985
Equation 39
I OUT
I SW = -------------  2 A
1–D
where ISW is the average current in the embedded power MOSFET in the on-time.
To chose the right value of the inductor and to manage transient output current, which can
exceed the maximum output current calculated by Equation 39 for a short time, also the
peak current in the power MOSFET must be calculated. The peak current, shown in
Equation 40, must be lower than the minimum current limit (2.5 A).
Equation 40
I OUT
r
I SW,PK = -------------  1 + ---  2.5A
1–D
2
V OUT
2
r = ------------------------------------   1 – D 
I OUT  L  F SW
where r is defined as the ratio between the inductor current ripple and the inductor DC
current:
So, in the buck-boost topology the maximum output current depends on the application
conditions (firstly input and output voltage, secondly switching frequency and inductor
value).
In Figure 35. the maximum output current for the above configuration is depicted varying the
input voltage from 4.5 V to 38 V.
The dashed line considers a more accurate estimation of the duty cycles given by Equation
41, where power losses across diodes, external power MOSFET, and internal power
MOSFET are taken into account.
Figure 35. Maximum output current according to max. DC switch current (2.0 A):
VO= 12 V
34/42
DocID022446 Rev 7
L7985
Application ideas
Equation 41
V OUT + 2  V D
D = -------------------------------------------------------------------------------------------V IN – V SW – V SWE + V OUT + 2  V D
where VD is the voltage drop across the diodes, VSW and VSWE across the internal and
external power MOSFET.
7.2
Inverting buck-boost
The L7985 device can implement the step-up/down converter with a negative output
voltage.
Figure 34 shows the schematic to regulate -5 V: no further external components are added
to the standard buck topology.
The relationship between input and output voltage is:
Equation 42
D
V OUT = – V IN  ------------1–D
so the duty cycle is:
Equation 43
V OUT
D = -----------------------------V OUT – V IN
As in the positive one, in the inverting buck-boost the current flowing through the power
MOSFET is transferred to the load only during the off-time. So, according to the maximum
DC switch current (2.0 A), the maximum output current can be calculated from Equation 38,
where the duty cycle is given by Equation 42.
Figure 36. Inverting buck-boost regulator
The GND pin of the device is connected to the output voltage so, given the output voltage,
the input voltage range is limited by the maximum voltage the device can withstand across
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42
Application ideas
L7985
VCC and GND (38 V). Therefore, if the output is -5 V, the input voltage can range from 4.5 V
to 33 V.
As in the positive buck-boost, the maximum output current according to application
conditions is shown in Figure 37. The dashed line considers a more accurate estimation of
the duty cycles given by Equation 44, where power losses across diodes and the internal
power MOSFET are taken into account.
Equation 44
V OUT – V D
D = ----------------------------------------------------------------– V IN – V SW + V OUT – V D
Figure 37. Maximum output current according to switch max. peak current (2.0 A):
VO = - 5 V
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L7985
8
Package information
Package information
In order to meet environmental requirements, ST offers these devices in different grades of
ECOPACK® packages, depending on their level of environmental compliance. ECOPACK
specifications, grade definitions and product status are available at: www.st.com.
ECOPACK is an ST trademark.
Figure 38. VFQFPN10 (3 x 3 x 1.08 mm) package outline
7
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42
Package information
L7985
Table 10. VFQFPN10 (3 x 3 x 1.08 mm) package mechanical data
(Dimensions) mm
Symbol
Min.
Typ.
Max.
0.80
0.90
1.00
A1
0.02
0.05
A2
0.70
A3
0.20
A
b
0.18
0.23
0.30
D
2.95
3.00
3.05
D2
2.21
2.26
2.31
E
2.95
3.00
3.05
E2
1.49
1.64
1.74
e
L
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0.50
0.3
0.40
M
0.75
m
0.25
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0.5
L7985
Package information
Figure 39. HSOP8 package outline
' PP7\S
( PP7\S
$0Y
Table 11. HSOP8 package mechanical data
(Dimensions) mm
Symbol
Min.
Typ.
A
Max.
1.70
A1
0.00
A2
1.25
b
0.31
0.51
c
0.17
0.25
D
4.80
4.90
5.00
E
5.80
6.00
6.20
E1
3.80
3.90
4.00
e
0.15
1.27
h
0.25
0.50
L
0.40
1.27
k
0.00
8.00
ccc
0.10
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Ordering information
9
L7985
Ordering information
Table 12. Order code
40/42
Order code
Package
Packaging
L7985A
HSOP8
Tube
L7985TR
VFQFPN10
Tape and reel
L7985ATR
HSOP8
Tape and reel
DocID022446 Rev 7
L7985
10
Revision history
Revision history
Table 13. Document revision history
Date
Revision
07-Nov-2011
1
Initial release.
01-Mar-2012
2
Section 8: Package information has been updated.
16-Oct-2012
3
In Section 5.6 changed temperature value from 130 to 120 °C.
18-Mar-2014
4
Updated text below Equation 4 on page 13 (replaced “DRC” by
“DCR”).
Numbered on page 22, Equation 28 on page 23, and Equation 32 on
page 25.
Updated Section 6.4.2: Type II compensation network on page 23
(added “” to “1 kand 5 k“in 1. on page 24).
Updated Figure 34: Positive buck-boost regulator on page 33
(replaced by a new figure).
Updated Section 8: Package information on page 37 (reversed order
of Figure 38 and Table 10, and Figure 39 and Table 11, minor
modifications).
Updated cross-references throughout document.
Minor modifications throughout document.
02-May-2014
5
Updated Table 12: Order code on page 40 (removed the L7985 order
code related to the VFQFPN10 in tube).
24-Jun-2014
6
Updated Figure 1: Application circuit on page 1 (replaced by new
figure).
Minor modifications throughout document.
7
Updated Figure 1: Application circuit on page 1 (replaced by new
figure).
Updated Section 5.1: Oscillator and synchronization on page 9
(added “typically” between “frequency” and “works”, and “The
SYNCH circuitry is also able to synchronize with a slightly lower
external frequency, so the frequency pre-adjustment with the same
resistor on the FSW pin, as described below, is suggested for
a proper operation.”).
Minor modifications throughout document.
05-Sep-2014
Changes
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L7985
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