STMICROELECTRONICS L6711TR

L6711
3 Phase controller with dynamic VID and selectable DACs
Features
■
2A integrated gate drivers
■
Fully differential current reading across
inductor or LS MOSFET
■
0.5% Output voltage accuracy
■
6 bit programmable output from 0.8185V to
1.5810V in 12.5mV steps
■
5 bit programmable output from 0.800V to
1.550V in 25mV steps
■
Dynamic VID management
■
Adjustable reference voltage offset
■
3% active current sharing accuracy
■
Digital 2048 step soft-start
■
Programmable over voltage protection
■
Integrated temperature sensor
■
Constant over current protection
■
Oscillator internally fixed at 150kHz (450kHz
ripple) externally adjustable
■
Output enable
■
Integrated remote sense buffer
■
TQFP48 7x7 Package with exposed pad
TQFP48 (Exposed Pad)
Description
The device implements a three phase step-down
controller with a 120° phase-shift between each
phase with integrated high current drivers in a
compact 7x7mm body package with exposed pad.
The device embeds selectable DAC: the output
voltage ranges from 0.8185V to 1.5810V with
12.5mV steps (VID_SEL = OPEN) or from 0.800V
to 1.550V with 25mV steps (VID_SEL = GND;
VID5 drives an optional +25mV offset) managing
dynamic VID with 0.5% accuracy over line and
temp variations. Additional programmable offset
can be added to the voltage reference with a
single external resistor.
The device assures a fast protection against load
over current and load over/under voltage. An
internal crowbar is provided turning on the low
side mosfet if an over-voltage is detected.
Applications
■
High current VRM/VRD for desktop / Server /
Workstation CPUs
In case of over-current, the system works in
Constant Current mode until UVP.
■
High density DC/DC Converters
Selectable current reading adds flexibility in
system design.
Order codes
April 2006
Part Number
Package
Packing
L6711
TQFP48
Tube
L6711TR
TQFP48
Tape & Reel
Rev 4
1/50
www.st.com
50
Contents
L6711
Contents
1
2
Typical application circuit and block diagram . . . . . . . . . . . . . . . . . . . . 4
1.1
Application circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.2
Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Pins description and connection diagrams . . . . . . . . . . . . . . . . . . . . . . 7
2.1
3
Pin descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
3.1
Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
3.2
Thermal data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
4
Electrical specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
5
VID Tables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
6
Device description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
7
Current reading and current sharing control loop . . . . . . . . . . . . . . . . 19
7.1
Low-side current reading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
7.2
Inductor current reading . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
8
DAC Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
9
Remote voltage sense . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
10
Voltage positioning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
11
2/50
10.1
Droop function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
10.2
Offset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
10.3
Integrated thermal sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
Dynamic VID transitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
11.1
VID_SEL = OPEN. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
11.2
VID_SEL = GND. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
L6711
Contents
12
Enable and disable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
13
Soft start . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
14
Output voltage monitor and protections . . . . . . . . . . . . . . . . . . . . . . . . 33
14.1
UVP protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
14.2
Programmable OVP protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
14.3
Preliminary OVP protection (Pre-OVP) . . . . . . . . . . . . . . . . . . . . . . . . . . 33
14.4
Over current . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
14.5
Low side sense overcurrent (CS_SEL=OPEN) . . . . . . . . . . . . . . . . . . . . 35
14.6
14.5.1
TON Limited output voltage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
14.5.2
Constant current operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
Inductor sense over current (CS_SEL = SGND) . . . . . . . . . . . . . . . . . . . 37
15
Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
16
Driver section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
16.1
Power dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
17
System control loop compensation . . . . . . . . . . . . . . . . . . . . . . . . . . . 41
18
Layout guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
18.1
Power connections. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
18.2
Power connections related. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
18.3
Current sense connections. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
19
Embedding L6711-based VRDs... . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47
20
TQFP48 Mechanical data & package dimensions . . . . . . . . . . . . . . . . 48
21
Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
3/50
Typical application circuit and block diagram
L6711
1
Typical application circuit and block diagram
1.1
Application circuit
Figure 1.
Typical application circuit for LS MOSFET current sense
VIN
LIN
1
GNDIN
41
38
4
5,31
22
6
CIN
VCCDR1
VCCDR2
VCCDR3
BOOT1
UGATE1
VCC
PHASE1
SGND
LGATE1
OSC/FAULT
OFFSET
PGND1
CS1-
20
21
9
TC
CS1+
CS_SEL
BOOT2
OVP
23
VID5
28
VID4
27
VID3
26
VID2
25
VID1
24
VID0
29
VID_SEL
13
OUTEN
L6711
UGATE2
VID5
VID4
VID3
VID2
VID1
PHASE2
LGATE2
PGND2
VID0
CS2-
VID_SEL
OUTEN
CS2+
BOOT3
7
COMP
UGATE3
CF
RF
PHASE3
8
FB
LGATE3
PGND3
RFB
10
11
12
L6711 REF. SCH. (MOSFET)
4/50
CS3VSEN
CS3+
FBR
FBG
SS_END
N.C.
37
N.C.
48
45
46
HS1
L1
47
2
LS1
3
14
Rg
15
Rg
44
43
HS2
42
Vcc_core
L2
40
COUT
LS2
LOAD
39
16
Rg
17
Rg
34
33
HS3
32
L3
36
LS3
35
18
Rg
19
Rg
30
SS_END
L6711
Typical application circuit and block diagram
Figure 2.
Typical application circuit for inductor DCR current sense
VIN
LIN
1
GNDIN
41
38
4
5,31
22
6
CIN
VCCDR1
VCCDR2
VCCDR3
BOOT1
UGATE1
VCC
PHASE1
SGND
LGATE1
OSC/FAULT
OFFSET
PGND1
CS1-
20
21
9
TC
CS1+
CS_SEL
BOOT2
OVP
23
VID5
28
VID4
27
VID3
26
VID2
25
VID1
24
VID0
29
VID_SEL
13
OUTEN
L6711
UGATE2
VID5
VID4
VID3
VID2
VID1
PHASE2
LGATE2
PGND2
VID0
CS2-
VID_SEL
OUTEN
CS2+
BOOT3
7
COMP
UGATE3
CF
RF
PHASE3
8
FB
LGATE3
PGND3
RFB
10
11
12
L6711 REF. SCH. (INDUCTOR)
CS3VSEN
CS3+
FBR
FBG
SS_END
N.C.
37
45
46
HS1
47
L1
2
LS1
Rg(RC)
3
Cg
14
Rg
15
Rg(a)
44
43
HS2
42
Vcc_core
L2
40
LS2
Rg(RC)
COUT
LOAD
39
Cg
16
Rg
17
Rg(a)
34
33
HS3
32
L3
36
LS3
Rg(RC)
35
Cg
18
R
19
Rg(a)
SS_END
30
N.C.
48
5/50
Typical application circuit and block diagram
Block diagram
OUTEN
OUTEN
HS1
HS1
3 PHASE
OSCILLATOR
LS2
PGND3
LGATE3
LS3
12.5µA
LOGIC PWM
ADAPTIVE ANTI
CROSS CONDUCTION
CURRENT SHARING
CORRECTION
PWM1
VCCDR3
PHASE3
HS3
LOGIC PWM
ADAPTIVE ANTI
CROSS CONDUCTION
CURRENT SHARING
CORRECTION
UGATE3
BOOT3
PGND2
LGATE2
VCCDR2
PHASE2
UGATE2
HS2
LOGIC PWM
ADAPTIVE ANTI
CROSS CONDUCTION
OSC
BOOT2
PGND1
LGATE1
PHASE1
VCCDR1
Block diagram
BOOT1
Figure 3.
UGATE1
1.2
L6711
OVP
OVP
VCC
CURRENT SHARING
CORRECTION
PWM2
VCC
SGND
PWM3
CS_SEL
PWM1
PWM2
AVERAGE CURRENT
TC
PWM3
DIGITAL
SOFT START
OUTEN
VCC
TEMPERATURE
COMPENSATION
VCCDR
CS_SEL
L6711
CONTROL LOGIC
AND PROTECTIONS
OCP1
OCP2
CH3 CURRENT
READING
DAC
WITH DYNAMIC
VID CONTROL
CH2 CURRENT
READING
OCP3
VID5
OFFSET
CH1 CURRENT
READING
TOTAL CURRENT
IDROOP
VID4
IOS
VID3
CS2CS2+
OCP2
ITC
VID2
CS3+
OCP3
VID0
VID1
CS3-
OVP
115% / OVP
CS1CS1+
OCP1
64k
VID_SEL
64k
SS_END
ERROR AMPLIFIER
IOS
REMOTE
BUFFER
64k
6/50
FBG
FBR
VSEN
COMP
FB
OFFSET
IFB
1.240V
64k
L6711
Pins description and connection diagrams
VID1
VID2
VID3
VID4
VID_SEL
SS_END
SGND
PHASE3
UGATE3
Pins connection (top view)
BOOT3
Figure 4.
PGND3
Pins description and connection diagrams
LGATE3
2
36 35 34 33 32 31 30 29 28 27 26 25
37
24
VID0
VCCDR3
38
23
VID5
PGND2
39
22
OSC / FAULT
LGATE2
40
21
CS_SEL
VCCDR2
41
20
TC
PHASE2
42
19
CS3+
UGATE2
43
18
CS3-
BOOT2
44
17
CS2+
BOOT1
45
16
CS2-
UGATE1
46
15
CS1+
PHASE1
47
14
CS1-
N.C.
48
13
OUTEN
5
6
7
8
PGND1
VCC
SGND
OFFSET
COMP
FB
2.1
Pin descriptions
Table 1.
Pins description
9 10 11 12
FBG
4
FBR
3
VSEN
2
OVP
1
LGATE1
L6711
VCCDR1
N.C.
N°
Name
1
VCCDR1
Channel 1 LS driver supply: it can be varied from 5V to 12V buses.
It must be connected together with other VCCDRx pins.
Filter locally with at least 1µF ceramic cap vs. PGND1.
2
LGATE1
Channel 1 LS driver output.
A little series resistor helps in reducing device-dissipated power.
3
PGND1
Channel 1 LS driver return path.
Connect to Power Ground Plane.
4
VCC
5
SGND
6
OFFSET
7
COMP
Description
Device supply voltage. The operative supply voltage is 12V ±15%.
Filter with 1µF capacitor (Typ.) vs. SGND.
All the internal references are referred to this pin. Connect it to the PCB signal ground.
Offset programming pin, internally fixed at 1.240V.
Short to SGND to disable the offset generation or connect through a resistor ROFFSET to
SGND to program an offset (positive or negative, depending on TC status) to the regulated
output voltage as reported in the relative section.
This pin is connected to the error amplifier output and is used to compensate the control
feedback loop.
7/50
Pins description and connection diagrams
Table 1.
L6711
Pins description (continued)
N°
Name
8
FB
This pin is connected to the error amplifier inverting input and is used to compensate the
voltage control feedback loop.
Connecting a resistor between this pin and VSEN pin allows programming the droop effect.
OVP
Over Voltage protection setup pin: it allows programming the OVP intervention.
Internally pulled-up to 5V, it sources a constant 12.5µA current.
Leaving the pin floating the OVP threshold is set to 115% (Typ.) of the programmed voltage
Connecting a resistor ROVP to SGND, it sets the OVP threshold to a fixed programmable
voltage (see relevant section for further details). Filter with 10nF vs. SGND in this case.
10
VSEN
Manages Over&Under-voltage conditions. It is internally connected with the output of the
Remote Sense Buffer for Remote Sense of the regulated voltage.
If no Remote Sense is implemented, connect it directly to the regulated voltage in order to
manage OVP and UVP.
11
FBR
Remote sense buffer non-inverting input.
It has to be connected to the positive side of the load to perform a remote sense.
12
FBG
Remote sense buffer inverting input.
It has to be connected to the negative side of the load to perform a remote sense.
9
13
14
15
16
8/50
Description
OUTEN
Output Enable pin; internally 3V pulled-up, it can be pulled-up with a resistor up to 3.3V.
If forced to a voltage lower than 0.3V, the device stops operation with all mosfets OFF: all the
protections are disabled in this condition except pre-OVP.
Cycle this pin to recover latch from protections; filter with 1nF (Typ.) capacitor vs. SGND.
CS1-
Channel 1 Current Sense Negative Input pin.
It must be connected through an Rg resistor to the LS mosfet drain (or to the LS-side of the
sense resistor placed in series to the LS mosfet) if LS mosfet sense is performed
(CS_SEL=OPEN). Otherwise (CS_SEL=SGND), it must be connected to the output-side of
the output inductor (or the output-side of the sense resistor used and placed between the
channel 1 inductor and the output of the converter) through Rg resistor.
The net connecting the pin to the sense point must be routed as close as possible to the CS1+
net in order to couple in common mode any picked-up noise.
CS1+
Channel 1 Current Sense Positive Input pin.
It must be connected through an Rg resistor to the LS mosfet source (or to the GND-side of
the sense resistor placed in series to the LS mosfet) if LS mosfet sense is performed
(CS_SEL=OPEN). Otherwise (CS_SEL=SGND), it must be connected to the phase-side of
the output inductor (or the inductor-side of the sense resistor used and placed between the
channel 1 inductor and the output of the converter) through Rg resistor and an R-C network
across the inductor.
The net connecting the pin to the sense point must be routed as close as possible to the CS1net in order to couple in common mode any picked-up noise.
CS2-
Channel 2 Current Sense Negative Input pin.
It must be connected through an Rg resistor to the LS mosfet drain (or to the LS-side of the
sense resistor placed in series to the LS mosfet) if LS mosfet sense is performed
(CS_SEL=OPEN). Otherwise (CS_SEL=SGND), it must be connected to the output-side of
the output inductor (or the output-side of the sense resistor used and placed between the
channel 2 inductor and the output of the converter) through Rg resistor.
The net connecting the pin to the sense point must be routed as close as possible to the CS2+
net in order to couple in common mode any picked-up noise.
L6711
Table 1.
N°
17
18
19
20
21
22
Pins description and connection diagrams
Pins description (continued)
Name
Description
CS2+
Channel 2 Current Sense Positive Input pin.
It must be connected through an Rg resistor to the LS mosfet source (or to the GND-side of
the sense resistor placed in series to the LS mosfet) if LS mosfet sense is performed
(CS_SEL=OPEN). Otherwise (CS_SEL=SGND), it must be connected to the phase-side of
the output inductor (or the inductor-side of the sense resistor used and placed between the
channel 2 inductor and the output of the converter) through Rg resistor and an R-C network
across the inductor.
The net connecting the pin to the sense point must be routed as close as possible to the CS2net in order to couple in common mode any picked-up noise.
CS3-
Channel 3 Current Sense Negative Input pin.
It must be connected through an Rg resistor to the LS mosfet drain (or to the LS-side of the
sense resistor placed in series to the LS mosfet) if LS mosfet sense is performed
(CS_SEL=OPEN). Otherwise (CS_SEL=SGND), it must be connected to the output-side of
the output inductor (or the output-side of the sense resistor used and placed between the
channel 3 inductor and the output of the converter) through Rg resistor.
The net connecting the pin to the sense point must be routed as close as possible to the CS3+
net in order to couple in common mode any picked-up noise.
CS3+
Channel 3 Current Sense Positive Input pin.
It must be connected through an Rg resistor to the LS mosfet source (or to the GND-side of
the sense resistor placed in series to the LS mosfet) if LS mosfet sense is performed
(CS_SEL=OPEN). Otherwise (CS_SEL=SGND), it must be connected to the phase-side of
the output inductor (or the inductor-side of the sense resistor used and placed between the
channel 3 inductor and the output of the converter) through Rg resistor and an R-C network
across the inductor.
The net connecting the pin to the sense point must be routed as close as possible to the CS3net in order to couple in common mode any picked-up noise.
TC
Temperature Compensation pin.
Connect through a resistor RTC and filter with 10nF vs. SGND to program the temperature
compensation effect.
Short to SGND to disable the compensation effect.
CS_SEL
Current Reading Selection pin, internally 5V pulled-up.
Leave floating to sense current across low-side mosfets or a sense resistor placed in series to
the LS mosfet source. Maximum duty cycle is dynamically limited and Track&Hold is enabled
to assure proper reading of the current.
Short to SGND to read current across inductors or a sense resistor placed in series to the
output inductors. No duty cycle limitation and no Track&Hold performed in this case.
OSC /
FAULT
Oscillator pin.
It allows programming the switching frequency of each channel: the equivalent switching
frequency at the load side results in being tripled.
Internally fixed at 1.24V, the frequency is varied proportionally to the current sunk (forced)
from (into) the pin with an internal gain of 6kHz/µA (See relevant section for details).
If the pin is not connected, the switching frequency is 150kHz for each channel (450kHz on the
load).
The pin is forced high (5V Typ.) when an Over/Under Voltage is detected; to recover from this
condition, cycle VCC or the OUTEN pin.
9/50
Pins description and connection diagrams
Table 1.
N°
L6711
Pins description (continued)
Name
Description
VID5,
VID0-4
Voltage IDentification pins.
Internally pulled-up to 3V, connect to SGND to program a logic ‘0’ while leave floating (as well
as pull-up with a resistor up to 3.3V) to program a logic ‘1’.
They are used to program the output voltage as specified in Table 5 and Table 6 together with
VID_SEL and to set the OVP/UVP protection thresholds accordingly.
See relevant section for details about DAC selection.
29
VID_SEL
VID_SELect pin. Through this pin it is possible to select the DAC table used for the regulation.
Leave floating to use a VRD10.x compliant DAC (See Table 1) while short to SGND to use a
VRM-Hammer compliant DAC (See Table 3).
See relevant section for details about DAC selection.
30
SS_END
Soft start end signal. It is an open collector output, set free after finishing the soft start.
Pull-up with a resistor to a voltage lower than 5V, if not used may be left floating.
31
SGND
All the internal references are referred to this pin. Connect it to the PCB signal ground.
32
PHASE3
Channel 3 HS driver return path. It must be connected to the HS3 mosfet source and provides
the return path for the HS driver of channel 3.
33
UGATE3
Channel 3 HS driver output.
A little series resistor helps in reducing device-dissipated power.
34
BOOT3
Channel 3 HS driver supply. This pin supplies the relative high side driver.
Connect through a capacitor (100nF Typ.) to the PHASE3 pin and through a diode to VCC
(cathode vs. boot).
35
PGND3
Channel 3 LS driver return path.
Connect to Power Ground Plane.
36
LGATE3
Channel 3 LS driver output.
A little series resistor helps in reducing device-dissipated power.
37
N.C.
38
VCCDR3
39
PGND2
Channel 2 LS driver return path.
Connect to Power Ground Plane.
40
LGATE2
Channel 2 LS driver output.
A little series resistor helps in reducing device-dissipated power.
41
VCCDR2
Channel 2 LS driver supply: it can be varied from 5V to 12V buses.
It must be connected together with other VCCDRx pins.
Filter locally with at least 1µF ceramic cap vs. PGND2.
42
PHASE2
Channel 2 HS driver return path. It must be connected to the HS2 mosfet source and provides
the return path for the HS driver of channel 2.
43
UGATE2
Channel 2 HS driver output.
A little series resistor helps in reducing device-dissipated power.
44
BOOT2
Channel 2 HS driver supply. This pin supplies the relative high side driver.
Connect through a capacitor (100nF Typ.) to the PHASE2 pin and through a diode to VCC
(cathode vs. boot).
23, 24
to 28
10/50
Not internally connected.
Channel 3 LS driver supply: it can be varied from 5V to 12V buses.
It must be connected together with other VCCDRx pins.
Filter locally with at least 1µF ceramic cap vs. PGND3.
L6711
Pins description and connection diagrams
Table 1.
Pins description (continued)
N°
Name
45
BOOT1
Channel 1 HS driver supply. This pin supplies the relative high side driver.
Connect through a capacitor (100nF Typ.) to the PHASE1 pin and through a diode to VCC
(cathode vs. boot).
46
UGATE1
Channel 1 HS driver output.
A little series resistor helps in reducing device-dissipated power.
47
PHASE1
Channel 1 HS driver return path. It must be connected to the HS1 mosfet source and provides
the return path for the HS driver of channel 1.
48
N.C.
PAD
Description
Not internally connected.
Thermal pad connects the silicon substrate and makes a good thermal contact with the PCB to
THERMAL
dissipate the power necessary to drive the external mosfets. Connect to the GND plane with
PAD
several vias to improve thermal conductivity.
11/50
Maximum ratings
L6711
3
Maximum ratings
3.1
Absolute maximum ratings
Table 2.
Absolute maximum ratings
Symbol
Parameter
Value
Unit
15
V
15
V
15
V
LGATEx, PHASEx to PGNDx
-0.3 to
Vcc+0.3
V
VID0 to VID5
-0.3 to 5
V
All other pins to PGNDx
-0.3 to 7
V
26
V
±1500
V
±2000
V
Value
Unit
VCC, VCCDRx To PGNDx
VBOOTxVPHASEx
Boot Voltage
VUGATExVPHASEx
VPHASEx
Sustainable Positive Peak Voltage. T<20nS @ 600kHz
CS3- Pin
Maximum Withstanding Voltage Range
Test Condition: CDF-AEC-Q100-002”Human Body Model”
OTHER PINS
Acceptance Criteria: “Normal Performance”
3.2
Thermal data
Table 3.
Symbol
Parameter
RthJA
Thermal Resistance Junction to Ambient
(Device soldered on 2s2p PC Board)
40
°C / W
TMAX
Maximum junction temperature
150
°C
TSTG
Storage temperature range
-40 to 150
°C
0 to 125
°C
2.5
W
TJ
PTOT
12/50
Thermal data
Junction Temperature Range
Max power dissipation at TA = 25°C
L6711
4
Electrical specifications
Electrical specifications
Table 4.
Symbol
Electrical characteristcs
(VCC=12V±15%, TJ = 0°C to 70°C unless otherwise specified)
Parameter
Test condition
Min.
Typ.
Max.
Unit
VCC supply current
VCC supply current
HGATEx and LGATEx open
VCCDRx=VBOOTx=12V
18
23
mA
ICCDRx
VCCDRx supply
current
LGATEx open; VCCDRx=12V
1.5
2
mA
IBOOTx
BOOTx supply current
HGATEx open;PHASEx to
PGNDx
VCC=BOOTx=12V
1
1.5
mA
Turn-On VCC
threshold
VCC Rising; VCCDRx=5V
8.2
9.2
10.2
V
Turn-Off VCC
threshold
VCC Falling; VCCDRx=5V
6.5
7.5
8.5
V
Turn-On VCCDRx
Threshold
VCCDRx Rising
VCC=12V
4.2
4.4
4.6
V
Turn-Off VCCDRx
Threshold
VCCDRx Falling
VCC=12V
4.0
4.2
4.4
V
OSC = OPEN
OSC = OPEN; TJ=0 to 125°C
135
127
150
165
178
kHz
kHz
0.3
V
ICC
Power-ON
Oscillator and inhibit
fOSC
Initial Accuracy
OUTEN IL
Output Enable
Threshold
OUTENIH
dMAX
Maximum duty cycle
∆Vosc
Ramp Amplitude
FAULT
Voltage at pin OSC
Input Low
Input High
0.5
OSC = OPEN: CS_SEL =
OPEN;
IFB=0
72
80
%
OSC = OPEN; CS_SEL =
OPEN;
IFB=105µA
30
40
%
3
V
OVP or UVP Active
4.70
V
5.0
5.30
V
13/50
Electrical specifications
Table 4.
L6711
Electrical characteristcs (continued)
(VCC=12V±15%, TJ = 0°C to 70°C unless otherwise specified)
Symbol
Parameter
Test condition
Min.
Typ.
Max.
Unit
VRD10.x DAC
FBR = VOUT; FBG = GNDOUT
-0.5
-
0.5
%
HAMMER DAC
FBR = VOUT; FBG = GNDOUT
-0.6
-
0.6
%
3
4.5
6
µA
Reference and DAC
Output Voltage
Accuracy
IVID,
IVID_SEL
VIDIL
VID, VID_SEL
pull-up Current
VIDx = GND
VID_SEL=GND
VID, VID_SEL
pull-up Voltage
VIDx = OPEN
VID_SEL = OPEN
VID, VID_SEL
Threshold
Input Low
Input High
VID IH
3
V
0.4
0.8
V
V
Error amplifier
A0
DC Gain
SR
Slew-Rate
80
dB
15
V/µs
DC Gain
1
V/V
Common Mode
Rejection Ratio
40
dB
15
V/µs
50
µA
50
µA
COMP = 10pF
Differential amplifier (remote buffer)
CMRR
SR
Slew Rate
VSEN = 10pF
Differential current sensing and offset
ICSx-
Bias Current
ICSx+
Bias Current
ILOAD = 0
I INFOx – I AVG Current Sense
----------------------------------Mismatch
IAVG
IOCTH
Over Current
Threshold
-3
-
3
•%
30
35
40
µA
-3.5
-
+3.5
µA
ILOAD =0; IOFFSET =100µA;
TC = SGND
-90
-100
-110
µA
ILOAD=0; IOFFSET =100mA;
TC Enabled
90
100
110
µA
0
-
250
µA
ICSx-(OCP)-ICSx-(0)
Droop Current
OFFSET = TC = SGND
deviation from nominal
IFB = 0 to 75µA
value
IFB
Offset Current
14/50
IOFFSET
OFFSET pin Current
Range
VOFFSET
OFFSET pin Voltage
IOFFSET = 0 to 250µA
1.240
V
L6711
Electrical specifications
Table 4.
Electrical characteristcs (continued)
(VCC=12V±15%, TJ = 0°C to 70°C unless otherwise specified)
Symbol
Parameter
Test condition
Min.
Typ.
Max.
Unit
0.612 0.645
0.593 0.625
0.530 0.558
0.677
0.656
0.586
V
30
ns
Thermal sensor
VTC
TC Voltage at
Tamb = 27ºC
RTC=100kΩ
RTC=50kΩ
RTC=5kΩ
Gate drivers
High Side
Rise Time
BOOTx-PHASEx=10V;
CHGATEx to PHASEx=3.3nF
15
IHGATEx
High Side
Source Current
BOOTx-PHASEx=10V
2
RHGATEx
High Side
Sink Resistance
BOOTx-PHASEx=12V;
Low Side
Rise Time
ILGATEx
R LGATEx
tRISE HGATE
tRISE LGATE
A
2
2.5
Ω
VCCDRx=10V;
CLGATEx to PGNDx=5.6nF
30
55
ns
Low Side
Source Current
VCCDRx=10V
1.8
Low Side
Sink Resistance
VCCDRx=12V
1.5
0.7
1.1
A
1.5
Ω
0.4
V
1
µA
Protections and SS_END
VSS_ENDL
SS_END Voltage Low
ISS_END = -4mA
ISS_ENDH
SS_END Leakage
VSS_END = 5V
UVP
Under Voltage Trip
VSEN Falling
55
60
65
%
Over Voltage
Threshold
VSEN Rising;
OVP = OPEN
112
115
118
%
Over Voltage
Threshold
VSEN Rising;
OVP = 90kΩ• to SGND
1.54
1.64
1.74
V
OVP
Turn-ON Threshold
Preliminary
PreOVP Threshold
OVP
PreOVP Hysteresis
VCC = VCCDRx Rising
FBR Rising
4
V
1.8
V
350
mV
15/50
VID Tables
5
L6711
VID Tables
Table 5.
Voltage IDentification (VID) Codes.
VID_SEL = OPEN (VRD 10.x DAC with -19mV auto-offset)
VID5 VID4 VID3 VID2 VID1 VID0
Note:
16/50
Output
Output
VID5 VID4 VID3 VID2 VID1 VID0
(V)
(V)
0
0
1
0
1
0
0.8185
0
1
1
0
1
0
1.1935
1
0
1
0
0
1
0.8310
1
1
1
0
0
1
1.2060
0
0
1
0
0
1
0.8435
0
1
1
0
0
1
1.2185
1
0
1
0
0
0
0.8560
1
1
1
0
0
0
1.2310
0
0
1
0
0
0
0.8685
0
1
1
0
0
0
1.2435
1
0
0
1
1
1
0.8810
1
1
0
1
1
1
1.2560
0
0
0
1
1
1
0.8935
0
1
0
1
1
1
1.2685
1
0
0
1
1
0
0.9060
1
1
0
1
1
0
1.2810
0
0
0
1
1
0
0.9185
0
1
0
1
1
0
1.2935
1
0
0
1
0
1
0.9310
1
1
0
1
0
1
1.3060
0
0
0
1
0
1
0.9435
0
1
0
1
0
1
1.3185
1
0
0
1
0
0
0.9560
1
1
0
1
0
0
1.3310
0
0
0
1
0
0
0.9685
0
1
0
1
0
0
1.3435
1
0
0
0
1
1
0.9810
1
1
0
0
1
1
1.3560
0
0
0
0
1
1
0.9935
0
1
0
0
1
1
1.3685
1
0
0
0
1
0
1.0060
1
1
0
0
1
0
1.3810
0
0
0
0
1
0
1.0185
0
1
0
0
1
0
1.3935
1
0
0
0
0
1
1.0310
1
1
0
0
0
1
1.4060
0
0
0
0
0
1
1.0435
0
1
0
0
0
1
1.4185
1
0
0
0
0
0
1.0560
1
1
0
0
0
0
1.4310
0
0
0
0
0
0
1.0685
0
1
0
0
0
0
1.4435
1
1
1
1
1
1
OFF
1
0
1
1
1
1
1.4560
0
1
1
1
1
1
OFF
0
0
1
1
1
1
1.4685
1
1
1
1
1
0
1.0810
1
0
1
1
1
0
1.4810
0
1
1
1
1
0
1.0935
0
0
1
1
1
0
1.4935
1
1
1
1
0
1
1.1060
1
0
1
1
0
1
1.5060
0
1
1
1
0
1
1.1185
0
0
1
1
0
1
1.5185
1
1
1
1
0
0
1.1310
1
0
1
1
0
0
1.5310
0
1
1
1
0
0
1.1435
0
0
1
1
0
0
1.5435
1
1
1
0
1
1
1.1560
1
0
1
0
1
1
1.5560
0
1
1
0
1
1
1.1685
0
0
1
0
1
1
1.5685
1
1
1
0
1
0
1.1810
1
0
1
0
1
0
1.5810
Since the VIDx pins program the maximum output voltage, according to VRD 10.x specs,
the device automatically regulates to a voltage 19mV lower avoiding use of any external
component to lower the regulated voltage. This improves the system tolerance performance
since the reference already offset is trimmed during production within ±0.5%.
L6711
VID Tables
Table 6.
Voltage IDentification (VID) Codes.
VID_SEL = SGND (Hammer DAC)
HAMMER DAC
HAMMER DAC +25mV
VID5 VID4 VID3 VID2 VID1 VID0
Output
Output
VID5 VID4 VID3 VID2 VID1 VID0
(V)
(V)
0
0
0
0
0
1.550
0
0
0
0
0
1.575
0
0
0
0
1
1.525
0
0
0
0
1
1.550
0
0
0
1
0
1.500
0
0
0
1
0
1.525
0
0
0
1
1
1.475
0
0
0
1
1
1.500
0
0
1
0
0
1.450
0
0
1
0
0
1.475
0
0
1
0
1
1.425
0
0
1
0
1
1.450
0
0
1
1
0
1.400
0
0
1
1
0
1.425
0
0
1
1
1
1.375
0
0
1
1
1
1.400
0
1
0
0
0
1.350
0
1
0
0
0
1.375
0
1
0
0
1
1.325
0
1
0
0
1
1.350
0
1
0
1
0
1.300
0
1
0
1
0
1.325
0
1
0
1
1
1.275
0
1
0
1
1
1.300
0
1
1
0
0
1.250
0
1
1
0
0
1.275
0
1
1
0
1
1.225
0
1
1
0
1
1.250
0
1
1
1
0
1.200
0
1
1
1
0
1.225
0
1
1
1
1
1.175
0
1
1
1
1
1.200
1
0
1
0
0
0
0
1.150
1
0
0
0
0
1.175
1
0
0
0
1
1.125
1
0
0
0
1
1.150
1
0
0
1
0
1.100
1
0
0
1
0
1.125
1
0
0
1
1
1.075
1
0
0
1
1
1.100
1
0
1
0
0
1.050
1
0
1
0
0
1.075
1
0
1
0
1
1.025
1
0
1
0
1
1.050
1
0
1
1
0
1.000
1
0
1
1
0
1.025
1
0
1
1
1
0.975
1
0
1
1
1
1.000
1
1
0
0
0
0.950
1
1
0
0
0
0.975
1
1
0
0
1
0.925
1
1
0
0
1
0.950
1
1
0
1
0
0.900
1
1
0
1
0
0.925
1
1
0
1
1
0.875
1
1
0
1
1
0.900
1
1
1
0
0
0.850
1
1
1
0
0
0.875
1
1
1
0
1
0.825
1
1
1
0
1
0.850
1
1
1
1
0
0.800
1
1
1
1
0
0.825
1
1
1
1
1
OFF
1
1
1
1
1
OFF
17/50
Device description
6
L6711
Device description
The device is a three phase PWM controller with embedded high current drivers that
provides complete control logic and protections for a high performance step-down DC-DC
voltage regulator optimized for advanced microprocessor power supply. Multi phase buck is
the simplest and most cost-effective topology employable to satisfy the increasing current
demand of newer microprocessors and modern high current DC/DC converters and POLs. It
allows distributing equally load and power between the phases using smaller, cheaper and
most common external power mosfets and inductors. Moreover, thanks to the 120° of phase
shift between each phase, the input and output capacitor count results in being reduced.
Phase interleaving causes in fact input rms current and output ripple voltage reduction and
show an effective output switching frequency increase: the 150kHz free-running frequency
per phase, externally adjustable through a resistor, results tripled on the output.
The controller includes multiple DACs, selectable through an apposite pin (VID_SEL),
allowing compatibility with both VRD 10.x and Hammer specifications, also performing DVID transitions accordingly. The output voltage can be precisely selected, programming the
VID and VID_SEL pins, from 0.8185V to 1.5810V with 12.5mV binary steps (VRD 10.x
compliant mode - 6 BIT with -19mV offset already programmed during production) or from
0.800V to 1.550V with 25mV steps (VRM Hammer compliant mode - 5 BIT, VID5 programs
a 25mV positive offset in this case), with a maximum tolerance on the output regulated
voltage of ±0.5% (±0.6% for Hammer) over temperature and line voltage variations.
The device permits easy and flexible system design by allowing current reading across
either inductor or low side mosfet in fully differential mode simply selecting the desired way
through the CS_SEL pin. In both cases, also a sense resistor in series to the related
element can be considered to improve reading precision. The current information read
corrects the PWM output in order to equalize the average current carried by each phase
limiting the error at ±3% over static and dynamic conditions unless considering the sensing
element spread.
The device provides a programmable Over-Voltage protection to protect the load from
dangerous over stress and can be externally set to a fixed voltage through an apposite
resistor or it can be set internally with a fixed percentage, latching immediately by turning
ON the lower driver and driving high the FAULT pin. Furthermore, preliminary OVP
protection also allows the device to protect load from dangerous OVP when VCC is not
above the UVLO threshold.
Over-Current protection provided, with an OC threshold for each phase, causes the device
to enter in constant current mode until the latched UVP. Depending on the reading mode
selected, the device keeps constant the peak (inductor sensing) or the valley (LS sensing)
of the inductor current ripple.
The device drives high the FAULT pin after each latching event: to recover it is enough to
cycle VCC or the OUTEN pin.
A compact 7x7mm body TQFP48 package with exposed thermal pad allows dissipating the
power to drive the external mosfet through the system board.
18/50
L6711
7
Current reading and current sharing control loop
Current reading and current sharing control loop
The device embeds a flexible, fully-differential current sense circuitry that is able to read
across both low side or inductor parasitic resistance or across a sense resistor placed in
series to that element. The fully-differential current reading rejects noise and allows placing
sensing element in different locations without affecting the measurement's accuracy. The
kind of sense element can be simply chosen through the CS_SEL pin: setting this pin free,
the LS mosfet is used while shorting it to SGND, the inductor will be used instead. Details
about connections are shown in Figure 5.
The high bandwidth current sharing control loop allows current balance even during load
transients: a current reference equal to the average of the read current (IAVG) is internally
built and the error between the read current and this reference is converted to a voltage that
with a proper gain is used to adjust the duty cycle whose dominant value is set by the
voltage error amplifier.
Figure 5.
Current reading connections selectable through CS_SEL pin.
CS_SEL
CS_SEL
LGATEx
PHASEx
IPHASE
L
RL
OUT
Rg
Rg(RC)
Cg
CSx-
CSx+
IPHASE
Rg(a)
Rg
CSx+
LS MOSFET Current Sense
7.1
CSx-
Rg
Inductor Current Sense
Low-side current reading
Leaving CS_SEL pin OPEN, the current flowing trough each phase is read using the voltage
drop across the low side mosfets R dsON or across a sense resistor in its series and it is
internally converted into a current. The transconductance ratio is issued by the external
resistor Rg placed outside the chip between CSx- and CSx+ pins toward the reading points
(see Figure 6 right). The proprietary current sense circuit tracks the current information for a
time TTRACK = TSW/3 (TSW = 1/FSW) centered in the middle of the low-side mosfet
conduction time (OFF Time, see Figure 6 left) and holds the tracked information during the
rest of the period.
This device sources a constant 50µA current from the CSx+ pin: the current reading circuitry
uses this pin as a reference and the reaction keeps the CSx- pin to this voltage during the
reading time (an internal clamp keeps CSx+ and CSx- at the same voltage sinking from the
CSx- pin the necessary current during the hold time; this is needed when LS mosfet R dsON
sense is implemented to avoid absolute maximum rating overcome on CSx- pin). The
current that flows from the CSx- pin is then given by the following equation (See Figure 6 right):
R dsON
R dsON
I CSx- = 50µA + ----------------- ⋅ I PHASEx = 50µA + I INFOx where: I INFOx = ----------------- ⋅ I PHASEx
Rg
Rg
RdsON is the on resistance of the low side mosfet and Rg is the transconductance resistor
used between CSx- and CSx+ pins toward the reading points; IPHASEx is the current carried
by the relative phase and I INFOx is the current information signal reproduced internally.
19/50
Current reading and current sharing control loop
L6711
50µA offset allows negative current reading, enabling the device to check for dangerous
returning current between the phases assuring the complete current equalization. From the
current information of each phase, information about the total current delivered (IDROOP =
IINFO1 + IINFO2 + IINFO3) and the average current for each phase (IAVG = (IINFO1 + IINFO2 +
IINFO3)/3 ) is taken. IINFOX is then compared to IAVG to give the correction to the PWMx
output in order to equalize the current carried by the three phases.
Figure 6.
IPHASEx
ILSx
IINFOx
Current reading across LS mosfet: timing (left) and circuit (right) for each
phase.
00 00 00 00 00
00000
000 000 000 000 000
00 00 00 00 00
00000
TTRACK
7.2
Rg
ICSx-
CSx-
IPHASEx
LGATEx
50µA
Rg
CSx+
TSW
Inductor current reading
Shorting CS_SEL pin to SGND, the current flowing trough each phase is read using the
voltage drop across the output inductor or across a sense resistor (RSENSE) in its series and
internally converted into a current. The transconductance ratio is issued by the external
resistor Rg placed outside the chip between CSx- and CSx+ pins toward the reading points
(see Figure 5 right).
The current sense circuit always tracks the current sensed and still sources a constant 50µA
current from the CSx+ pin: this pin is used as a reference keeping the CSx- pin to this
voltage. To correctly reproduce the inductor current an R-C filtering network must be
introduced in parallel to the sensing element.
The current that flows from the CSx- pin is then given by the following equation (See Figure
7):
I CSx-
L
⎛
⎞
1 + s ⋅ ------RL
RL ⎜
⎟
= 50µA + ------- ⋅ ⎜ ------------------------------------------------⎟ ⋅ I PHASEx
R g ⎜ 1 + s ⋅ Rg ( R C ) ⋅ Cg⎟
⎝
⎠
Where IP HASEx is the current carried by the relative phase.
Considering now to match the time constant between the inductor and the R-C filter applied
(Time constant mismatches cause the introduction of poles into the current reading network
causing instability. Moreover, it is also important for the load transient response and to let
the system show resistive equivalent output impedance), it results:
RL
RL
R g ( RC) ⋅ Cg ≥ I CSx- = 50µA + -------- ⋅ I PHASEx = 50µA + I I NFOx where IINFOx = I PHASEx ⋅ -------Rg
Rg
IINFOx is the current information reproduced internally.
50µA offset allows negative current reading, enabling the device to check for dangerous
returning current between the phases assuring the complete current equalization. From the
20/50
L6711
Current reading and current sharing control loop
current information of each phase, information about the total current delivered (IDROOP =
IINFO1 +IINFO2 + IINFO3) and the average current for each phase (IAVG = (IINFO1 + IINFO2 +
IINFO3)/3) is taken. IINFOX is then compared to IAVG to give the correction to the PWM output
in order to equalize the current carried by the three phases.
Since Rg is designed considering the OC protection, to allow further flexibility in the system
design, the resistor in series to CSx+ can be split in two resistors as shown in Figure 7.
Figure 7.
Inductor current sense
Design Equations:
L
R g ( RC ) = -----------------RL ⋅ Cg
R g ( RC ) + R g ( a ) = Rg
21/50
DAC Selection
8
L6711
DAC Selection
The device embeds a selectable DAC that allows the output voltage to have a tolerance of
±0.5% (0.6% for Hammer DAC) recovering from offsets and manufacturing variations. The
VID_SEL pin selects the DAC table used to program the reference for the regulation as
shown in Table .
Table 7.
DAC Selection
VID_SEL
Selected DAC
OPEN
VRM / VRD 10.x DAC.
Output voltage ranges from 0.8185V to 1.5810V with 12.5mV steps (See Table 5).
Since the VIDx pins program the maximum output voltage, according to VRD 10.x
specs, the device automatically regulates with –19mV offset avoiding use of any external
component to lower the regulated voltage.
Since the -19mV offset is programmed during the production stage, no further error is
introduced to generate the offset since it is automatically recovered during the trimming
stage.
VID5
Hammer DAC
OPEN
Output voltage ranges from 0.800V to 1.550V with 25mV steps (See Table 6).
SGND
Output voltage ranges from 0.825V to 1.575V with 25mV steps (See Table 6).
Since the +25mV offset is programmed during the production stage, no further
error is introduced to generate the offset since it is automatically recovered
during the trimming stage.
SGND
VID pins are inputs of an internal DAC that is realized by means of a series of resistors
providing a partition of the internal voltage reference. The VID code drives a multiplexer that
selects a voltage on a precise point of the divider. The DAC output is delivered to an
amplifier obtaining the voltage reference (i.e. the set-point of the error amplifier, VPROG).
Internal pull-ups are provided (realized with a 5µA current generator up to 3V Typ); in this
way, to program a logic "1" it is enough to leave the pin floating, while to program a logic "0"
it is enough to short the pin to SGND.
Programming the "11111x" code (NOCPU, VID5 is irrelevant), the device shuts down: all
mosfets are turned OFF and SS_END is shorted to SGND. Removing the code causes the
device to restart.
The voltage identification (VID) pin configuration also sets the Over / Under Voltage
protection (OVP/UVP) thresholds.
22/50
L6711
Remote voltage sense
The device embeds a Remote Sense Buffer to sense remotely the regulated voltage without
any additional external components. In this way, the output voltage programmed is
regulated between the remote buffer inputs compensating motherboard or connector
losses. The very low-offset amplifier senses the output voltage remotely through the pins
FBR and FBG (FBR is for the regulated voltage sense while FBG is for the ground sense)
and reports this voltage internally at VSEN pin with unity gain eliminating the errors.
Keeping the FBR and FBG traces parallel and guarded by a power plane results in common
mode coupling for any picked-up noise.
If remote sense is not required, it is enough connecting the resistor R FB directly to the
regulated voltage: VSEN becomes not connected and still senses the output voltage
through the remote buffer. In this case the FBG and FBR pins must be connected anyway to
the regulated voltage (See Figure 8).
Warning:
Remote buffer connections
64k
64k
VID
VID
COMP
RF
VSEN
FBR
FBG
64k
FB
COMP
RF
CF
VSEN
64k
FB
64k
64k
64k
Figure 8.
The remote buffer is included in the trimming chain in order
to achieve ±0.5% accuracy (0.6% for the Hammer DAC) on the
output voltage when the RB is used: eliminating it from the
control loop causes the regulation error to be increased by
the RB offset worsening the device performances!
64k
9
Remote voltage sense
FBR
FBG
CF
To Vcore
(Remote Sense)
RFB
RFB
To Vcore
RB used (up to ±0.5% Accuracy)
RB Not Used (Precision worsened)
23/50
Voltage positioning
10
L6711
Voltage positioning
Output voltage positioning is performed by selecting the reference DAC and by
programming the different contributors to the IFB current (see Figure 9). This current,
sourced from the FB pin, causes the output voltage to vary according to the external RFB
resistor: this allows programming precise output voltage variations depending on the
sensed current (Droop Function) as well as offsets for the regulation.
The three contributors to the IFB current value are:
●
Droop Function (green);
●
Offset (red);
●
Integrated Temperature Compensation (fuchsia).
Moreover, the embedded Remote Buffer allows to precisely programming the output voltage
offsets and variations by recovering the voltage drops across distribution lines.
The output voltage is then driven by the following relationship (IOFFSET sign depends on TC
setting):
VID – R FB ⋅ IFB = VID – R FB ⋅ ( I D ROOP ± I OFFSET – I TC )
Voltage positioning and droop function
ESR DROP
ITC
Figure 9.
64k
IOFFSET
IDROOP
VMAX
64k
FB
COMP
RF
VSEN
64k
IFB
64k
VID
FBR
FBG
VMIN
CF
To Vcore
(Remote Sense)
RFB
10.1
VNOM
RESPONSE WITHOUT DROOP
RESPONSE WITH DROOP
Droop function
Droop function allows the device to satisfy the requirements of high performance
microprocessors, reducing the size and the cost of the output capacitor. This method
"recovers" part of the drop due to the output capacitor ESR in the load transient, introducing
a dependence of the output voltage on the load current: a static error proportional to the
output current causes the output voltage to vary according to the sensed current. As shown
in figure 4-right, the ESR drop is present in any case, but using the droop function the total
deviation of the output voltage is minimized.
The information about the total current delivered (IDROOP) is sourced from the FB pin (see
Figure 9): connecting a resistor between this pin and VSEN (i.e. the output voltage), the total
current information flows only in this resistor because the compensation network between
FB and COMP has always a capacitor in series (CF, see Figure 9). The voltage regulated is
then equal to:
V OUT = VID – R FB ⋅ I DR OOP
Where VID is the reference programmed through VIDx and VID_SEL (Only the IDROOP
contribute to IFB has been considered).
24/50
L6711
Voltage positioning
Since IDROOP depends on the current information about the three phases, the output
characteristic vs. load current is given by:
R SENSE
VID – R FB ⋅ IDR OOP = VID – RFB ⋅ --------------------- ⋅ I OUT = VID – R DROOP ⋅ IOUT
Rg
Where RSENSE is the chosen sensing element resistance (Inductor DCR or LS RdsON), IOUT
is the output current of the system and R DROOP is its equivalent output resistance (The
whole power supply can be then represented by a "real" voltage generator with a voltage
value of VID and an equivalent series resistance RDROOP).
RFB resistor can be also designed according to the RDROOP specifications as follow:
Rg
R FB = R DROOP ⋅ --------------------R SEN SE
Figure 10. Voltage positioning with offset
64k
IOFFSET
OFFSET
IFB
64k
FB
ROFFSET
COMP
RF
VSEN
64k
VID
1:1
64k
TC
IOFFSET
1.240V
IDROOP
FBR
FBG
CF
To Vcore
(Remote Sense)
RFB
10.2
Offset
The OFFSET pin allows programming a positive or a negative offset (V OS) for the output
voltage.
When the Integrated Thermal Sensor is disabled (TC = SGND) a resistor R OFFSET
connected vs. SGND increases the output voltage: since the pin is internally fixed at 1.240V,
the current programmed by the resistor ROFFSET is mirrored and then properly subtracted
from the IFB current (see Figure 10) as follow (Only the IOFFSET contribute to IFB has been
considered):
1.240V
V OUT = VID + R FB ⋅ I OFFSET = VID + R FB ⋅ ⎛ ------------------------⎞ = VID + V OS
⎝R
⎠
OFFSET
The device will add the programmed offset VOS to the output programmed voltage
(considering now also the droop effect) subtracting the relative offset current from the
feedback current IFB:
VID – R FB ⋅ IFB = VID – R FB ⋅ ( I D ROOP – I OFFSET ) = VID + R FB ⋅ I OFFSET – R D ROOP ⋅ I OUT
25/50
Voltage positioning
L6711
Offset resistor can be designed by considering the following relationship (R FB is fixed by the
Droop effect):
1.240V
R OFFSET = ------------------- ⋅ R FB
V OS
Offset automatically given by the DAC selection or by VID5 when VID_SEL=SGND differs
from the offset implemented through the OFFSET pin: the built-in feature is trimmed in
production and assures ±0.5% error (±0.6% for the Hammer DAC) over load and line
variations while implementing the same offset through the OFFSET pin causes additional
errors to be considered in the total output voltage precision.
When the Integrated Thermal Sensor is enabled (see Figure 11 and following section), the
pin programs, in the same way as before, a negative offset. This is to compensate the
positive native offset introduced by the ITS. The effect of the programmed offset on the
output voltage results (IOFFSET is now added to IFB and no more subtracted as before):
1.240
V OUT = VID – R FB ⋅ I OFFSET = VID – R FB ⋅ ⎛ ------------------------⎞ = VID – V OS
⎝R
⎠
OFFSET
Offset resistor is designed to compensate the ITS native offset as described in the following
section.
The Offset function can be disabled by shorting the pin to SGND.
Voltage positioning with integrated thermal sensor
ITC
Figure 11.
1:1
64k
IOFFSET
ITC
TC
1:1
OFFSET
RTC
IDROOP
VID
IFB
64k
FB
ROFFSET
COMP
RF
VSEN
64k
IOFFET
1.240V
64k
VTC=A+B·(TJ-25)
FBR
FBG
CF
To Vcore
(Remote Sense)
RFB
10.3
Integrated thermal sensor
Current sense elements have non-negligible temperature variations: considering either
inductor or LS mosfet sense, the sensing elements modify proportionally to varying
temperature. As a consequence, the sensed current is subjected to a measurement error
that causes the regulated voltage to vary accordingly.
To recover from this temperature related error, a temperature compensation circuit is
integrated into the controller: the internal temperature is sensed and the droop current is
corrected (according to a scaling external resistor RTC) in order to keep constant the
regulated voltage.
26/50
L6711
Voltage positioning
The ITS circuit subtracts from the IFB current a current proportional to the sensed
temperature as follow (see Figure 11, Only the I DROOP and I TC contributes to IFB have been
considered):
R SEN SE ( T MOS )
V OUT ( T,I OUT ) = VID – R FB ⋅ ------------------------------------------ ⋅ IOUT – I TC ( T J )
Rg
1
R TC
where I TC ( T J ) = ----------- ⋅ [ A + B ⋅ ( T J – 25 ) ]
where A and B are positive constants depending on the value of the external resistor R TC
(see Figure 12), TJ is the device junction temperature and TMOS is the mosfet (or the used
sensing element) temperature.
The resistor RTC can be designed in order to zero the temperature influence on the output
voltage at a fixed current as follow:
R SENSE ⋅ α ⋅ ( T MOS – 25 )
R FB
– R FB ⋅ ------------------------------------------------------------------- ⋅ I OUT + ----------- ⋅ B ⋅ ( T J – 25 ) = 0
Rg
R TC
B⋅k
Rg
R SENSE α ⋅ I OUT
T
obtaining the following relationship: R TC = --------------------- ⋅ --------------------
where R SENSE is the sensing element resistance value (at TMOS = 25ºC), B is the constant
obtainable from
Figure 12, kT is the Temperature Coupling Coefficient between the sensing element and the
Controller (it results KT = (TJ-25)/(TMOS-25)) and α is the Temperature Coefficient of the
sensing element. Since RTC depends from the constant B depending in turn from RTC, an
iterative process is required to properly design the RTC value. As a consequence of the
nature of the thermal sensor, a negative offset is needed to compensate the native offset
introduced by the ITS at a referenced temperature Tref and it is obtainable by connecting a
ROFFSET resistor between the OFFSET pin and SGND as follow:
A + B ⋅ ( T ref – 25 )
I OFFSET = – I TC ( T ref ) = ---------------------------------------------R TC
To disable this function, short the pin to SGND.
Figure 12. Integrated thermal sensor constant vs. external resistor RTC
650
2.00
625
1.90
600
575
1.80
550
1.70
525
500
1.60
475
450
1.50
0
10 20 30 40 50 60 70 80 90 100
A [mV] vs. RTC [KΩ]
0
10 20 30 40 50 60 70 80 90 100
B [mV/°C] vs. R TC [KΩ]
27/50
Dynamic VID transitions
11
L6711
Dynamic VID transitions
The device is able to manage Dynamic VID Code changes that allow Output Voltage
modification during normal device operation.
OVP and UVP signals are masked during every VID transition and they are re-activated
after the transition finishes.
When changing dynamically the regulated voltage (D-VID), the system needs to charge or
discharge the output capacitor accordingly. This means that an extra-current ID-VID needs to
be delivered, especially when increasing the output regulated voltage and it must be
considered when setting the over current threshold. This current result:
C OUT ⋅ dV OUT
I D – VID = -------------------------------------dT VID
where dVOUT is the selected DAC LSB (12.5mV for VRD10.x or 25mV for Hammer DAC)
and TVID is the time interval between each LSB transition.
Overcoming the OC threshold during the dynamic VID causes the device to enter the
constant current limitation slowing down the output voltage dV/dt also causing the failure in
the D-VID test.
The way in which the device modifies the reference depends on the VID_SEL status and
then on the kind of DAC selected.
VID Sampled
VID Sampled
VID Sampled
VID Sampled
VID Stable
Ref Moved (1)
VID Sampled
VID Sampled
VID Stable
Ref Moved (1)
VID Sampled
VID Sampled
VID Stable
Ref Moved (1)
VID Sampled
VID Sampled
VID Stable
Ref Moved (1)
VID Sampled
VID Sampled
VID Sampled
VID Sampled
Ref Moved (4)
Ref Moved (3)
Ref Moved (2)
VID Sampled
VID Stable
Ref Moved (1)
VID Sampled
VID Sampled
Figure 13. Dynamic VID transition, VRD10.x DAC
VID Clock
t
VID [0,5]
t
Int. Reference
Tsw/3
Tsw
t
Vout
TVID
x 4 Step VID Transition
VRD10.x DAC
28/50
4 x 1 Step VID Transition - VRD10.x DAC
t
L6711
VID_SEL = OPEN.
Selecting the VRD10.x DAC, the device checks for VID code modifications on the rising
edge of a clock that is three times the switching frequency of each phase and waits for a
confirmation on the following falling edge. Once the new code is stable, on the next rising
edge, the reference starts stepping up or down in LSB increments (12.5mV) every clock
cycle (still 3·FSW) until the new VID code is reached. During the transition, VID code
changes are ignored; the device re-starts monitoring VID after the transition has finished on
the next rising edge available.
Warning:
if the new VID code is more than 1 LSB higher than the
previous, the device will execute the transition stepping the
reference with a frequency equal to 3·FSW until the new code
has reached: for this reason it is recommended to carefully
control the VID change rate in order to carefully control the
slope of the output voltage variation.
Warning:
DVID sample and hold clock depends on the switching
frequency FSW. To correctly perform DVID transition so
following the VID change rate, it is required to have at least 2
complete cycles of the FDVID clock between every VID
transition. If the VID update-rate is, for example, 5µs, the
minimum operating frequency results to be FSW > 133kHz.
VID Sampled
VID Sampled
Ref Moved (4)
Ref Moved (3)
Ref Moved (2)
Ref Moved (1)
VID Changed
VID Stable
VID Sampled
Figure 14. Dynamic VID Transition, Hammer DAC
VID Sampled
11.1
Dynamic VID transitions
VID Clock
VID [0,5]
t
t
Int. Reference
Tsw
t
Vout
4 Step VID Transition - Hammer DAC
t
29/50
Dynamic VID transitions
11.2
L6711
VID_SEL = GND.
Selecting the HAMMER DAC, the device checks for VID code modifications on the rising
edge of a clock that is the same frequency of each phase and waits for a confirmation on the
following falling edge. Once the new code is stable, on the next rising edge the reference
starts stepping up or down in LSB increments (25mV) every clock cycle until the new VID
code is reached. During the transition, VID code changes are ignored; the device re-starts
monitoring VID after the transition has finished on the next rising edge.
If the new VID code is more than 1 bit higher than the previous, the device will execute the
transition stepping the reference every switching cycle until the new code has reached
30/50
L6711
12
Enable and disable
Enable and disable
The device has three different supplies: VCC pin to supply the internal control logic,
VCCDRx to supply the low side drivers and BOOTx to supply the high side drivers. If the
voltage at pins VCC and VCCDRx are not above the turn on thresholds specified in the
Electrical Characteristics, the device is shut down: all drivers keep the mosfets off to show
high impedance to the load. Once the device is correctly supplied, proper operation is
assured but the device can be controlled in different ways:
●
OUTEN pin. It can be used to control the power sequencing in complex systems.
Setting the pin free, the device implements a soft start up to the programmed voltage.
Shorting the pin to SGND, it resets the device (SS_END is shorted to SGND in this
condition and protections are disabled except pre-OVP) from any latched condition and
also disables the device keeping all the mosfet turned off to show high impedance to
the load. It can be then cycled to recover from any latched condition such as OVP and
UVP.
●
NOCPU (VID [0;5]=11111x) In this condition (VID5 state is irrelevant) the device is
disabled and keeps all the mosfet turned off to show high impedance to the load.
Nevertheless, it waits for any VID code transition to power up implementing a soft start.
During this condition, SS_END pin is shorted to SGND.
31/50
Soft start
13
L6711
Soft start
During soft start, a ramp is generated increasing the loop reference from 0V to the final
value programmed by VID in 2048 clock periods as shown in
Figure 15. Once the soft start begins, the reference is increased: upper and lower MOS
begin to switch and the output voltage starts to increase with closed loop regulation. At the
end of the digital soft start, the SS_END signal is then driven high.
The Under Voltage comparator is enabled when the reference voltage reaches 0.6V while
Over Voltage Comparator is always enabled during soft start with a threshold equal to the
115% of the programmed reference or the threshold programmed by R OVP (see relevant
section).
Figure 15. Soft start
VCC=VCCDR
Turn ON threshold
VLGATEx
t
VOUT
t
SS_END
t
2048 Clock Cycles
t
(CH1=VOUT; CH2=LGATEx; CH3=SS_END)
32/50
L6711
14
Output voltage monitor and protections
Output voltage monitor and protections
The device monitors through pin VSEN the regulated voltage in order to manage the OVP /
UVP conditions.
14.1
UVP protection
If the output voltage monitored by VSEN drops below the 60% of the reference voltage for
more than one clock period, the device turns off all mosfets and the OSC/FAULT is driven
high (5V). The condition is latched; to recover it is required to cycle Vcc or the OUTEN pin.
14.2
Programmable OVP protection
Once VCC crosses the turn-ON threshold and the device is enabled (OUTEN = 1), the
device provides a programmable Over Voltage protection; when the voltage sensed
overcomes the programmed threshold, the controller permanently switches on all the lowside mosfets and switches off all the high-side mosfets in order to protect the load. The
OSC/ FAULT pin is driven high (5V) and power supply or OUTEN pin cycling is required to
restart operations.
The OVP threshold is programmed through the OVP pin: leaving the pin floating, it is
internally pulled-up and the threshold is set at 115% (Typ.) of the programmed output
voltage. Connecting the OVP pin to SGND through a resistor ROVP, the OVP threshold
becomes a fixed voltage as follow:
OVPTH = 1.455 · ROVP · 12.5µ
14.3
Preliminary OVP protection (Pre-OVP)
While VCC pin is under the turn-ON threshold, a preliminary-OVP protection turns on the
low side mosfets as long as the FBR pin voltage is greater than 1.8V. This protection is
enabled when VCC stays within the device turn-on threshold and the PreOVP turn on
threshold and depends also on the OUTEN pin status as detailed in Figure 16 - left.
A simple way to provide protection to the output in all conditions when the device is OFF
(then avoiding the unprotected red region in Figure 16) consists in supplying the controller
through the 5VSB bus as shown in Figure 16 - right.
Both Over Voltage and Under Voltage are active also during soft start (see the relevant
section).
33/50
Output voltage monitor and protections
L6711
Figure 16. Output voltage protections and typical principle connections to assure
complete protection.
+5VSB
Vcc
Vcc TurnON
(OUTEN = 0)
Preliminary OVP
FBR Monitored
(OUTEN = 1)
Programmable OVP
VSEN Monitored
+12V
Preliminary OVP Enabled
FBR Monitored
PreOVP TurnON
VCCDR1
VCCDR2
No Protection
Provided
14.4
VCC
VCCDR3
Over current
Depending on the current reading method selected, the device limits the peak or the bottom
of the inductor current entering in constant current until setting UVP as below explained.
The Over Current threshold has to be programmed, by designing the Rg resistors, to a safe
value, in order to be sure that the device doesn't enter OCP during normal operation of the
device. This value must take into consideration also the extra current needed during the
Dynamic VID Transition ID-VID and, since the device reads across mosfets RdsON or inductor
DCR, the process spread and temperature variations of these sensing elements.
Moreover, since also the internal threshold spreads, the Rg design must consider its
minimum value IOCTH(min) as follow:
IOCPx ( max ) ⋅ R SENSE ( max )
Rg = --------------------------------------------------------------------I OC TH ( min )
where I OCPx is the current measured by the current reading circuitry when the device enters
Quasi Constant Current (LS Mosfet Sense) or Constant Current (Inductor Sense), IOCPx
must be calculated starting from the corresponding output current value IOUT(OCP) as follow
(ID-VID must also be considered when D-VID are implemented):
I OCPx =
⎧
⎪
⎪
⎨
⎪
⎪
⎩
I OUT ( OCP ) ∆I pp I D -VID
--------------------------- – ----------- + -------------- Low Side Mosfet Sense
2
3
3
I OUT ( OCP ) ∆Ipp I D-VID
--------------------------- + ----------- + -------------- Inductor DCR Sense
2
3
3
where I OUT(OCP) is still the output current value at which the device enters Quasi Constant
Current (LS Mosfet Sense) or Constant Current (Inductor Sense),∆IPP is the inductor current
ripple in each phase and ID-VID is the additional current required by D-VID (when applicable).
In particular, since the device limits the peak or the valley of the inductor current (according
to CS_SEL status), the ripple entity, when not negligible, impacts on the real OC threshold
value and must be considered.
34/50
L6711
14.5
Output voltage monitor and protections
Low side sense overcurrent (CS_SEL=OPEN)
The device detects an Over Current condition for each phase when the current information
IINFOx overcomes the fixed threshold of IOCTH (35µA Typ). When this happens, the device
keeps the relative LS mosfet on, skipping clock cycles, until the threshold is crossed back
and IINFOx results being lower than the IOCTH threshold. This implies that the device limits
the bottom of each inductor current ripple.
After exiting the OC condition, the LS mosfet is turned off and the HS is turned on with a
duty cycle driven by the PWM comparator.
Keeping the LS on, skipping clock cycles, causes the on-time subsequent to the exit from
the OC condition to increase. Considering now that the device, with this kind of current
sense, has maximum on-time dependence with the delivered current given by the following
relationship:
T ON,MAX = ( 0.80 – ID ROOP ⋅ 3.8k ) ⋅ T SW =
⎧
⎪
⎨
⎪
⎩
0.80 ⋅ T SW I DROOP = 0µA
0.40 ⋅ T SW I DROOP = 105µA
Where IOUT is the output current (IOUT = Σ·IPHASEx) and TSW is the switching period (TSW
=1/FSW).
This linear dependence has a value at zero load of 0.80 ·TSW and at maximum current of
0.40 ·TSW typical and results in two different over current behaviors of the device:
14.5.1
TON Limited output voltage.
This happens when the maximum ON time is reached before that the current in each phase
reaches IOCPx (IINFOx<IOCTH). Figure 17 shows the maximum output voltage that the device
is able to regulate considering the TON limitation imposed by the previous relationship. If the
desired output characteristic crosses the TON limited maximum output voltage, the output
resulting voltage will start to drop after the crossing.
In this case, the device doesn't perform constant current limitation but only limits the
maximum ON time following the previous relationship. The output voltage starts to decrease
follows the resulting characteristic (dotted in Figure 17) until UVP is detected or anyway until
IDROOP =105µA.
Figure 17. TON limited operation
V
O
U
T
V
O
U
T
0
.8
0
·V
IN
0
.8
0
·V
IN
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0
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IO
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T
IO
=
3
·IO
C
P
C
P
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(ID
=
1
0
5
µ
A
)
R
O
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Maximum output Voltage
IO
=
3
·IO
C
P
C
P
x
(ID
=
1
0
5
µ
A
)
R
O
O
P
IO
U
T
b) TON Limited Output Voltage
35/50
Output voltage monitor and protections
14.5.2
L6711
Constant current operation
This happens when the on-time limitation is reached after the valley current in each phase
reaches IOCPx (IINFOx > IOCTH).
The device enters in Quasi-Constant-Current operation: the low-side mosfets stays ON until
the current read becomes lower than IOCPx (IINFOx < IOCTH) skipping clock cycles. The high
side mosfet can be then turned ON with a TON imposed by the control loop after the LS turnoff and the device works in the usual way until another OCP event is detected.
This means that the average current delivered can slightly increase in Quasi-ConstantCurrent operation since the current ripple increases. In fact, the ON time increases due to
the OFF time rise because of the current has to reach the IOCPx bottom. The worst-case
condition is when the ON time reaches its maximum value.
When this happens, the device works in Constant Current and the output voltage decrease
as the load increase. Crossing the UVP threshold causes the device to latch driving high the
OSC pin (Figure 18 shows this working condition).
It can be observed that the peak current (Ipeak) is greater than IOCPx but it can be
determined as follow:
V IN – Vout MI N
V I N – Vout MIN
I PEAK = I OC Px + -------------------------------------- ⋅ Ton MAX = I OCPx + -------------------------------------- ⋅ 0.40 ⋅ T SW
L
L
Where VoutMIN is the UVP threshold, (inductor saturation must be considered). When that
threshold is crossed, all mosfets are turned off, the FAULT pin is driven high and the device
stops working. Cycle the power supply or the OUTEN pin to restart operation.
The maximum average current during the Constant-Current behavior results:
Ipeak – I OCPx
I MAX,TOT = 3 ⋅ I MAX = 3 ⋅ ⎛ IOCPx + -------------------------------------⎞
⎝
⎠
2
In this particular situation, the switching frequency for each phase results reduced. The ON
time is the maximum allowed (TonMAX) while the OFF time depends on the application:
Ipeak – I OCPx
T OFF = L ⋅ ------------------------------------V out
1
F = --------------------------------------T onMax + T OFF
The transconductance resistor Rg can be designed considering that the device limits the
bottom of the inductor current ripple and also considering the additional current delivered
during the quasi-constant-current behavior as previously described in the worst case
conditions.
Moreover, when designing D-VID compatible systems, the additional current due to the
output filter charge during dynamic VID transitions must be considered.
IOCPx ( max ) ⋅ R SENSE ( max )
I OUT ( OCP ) ∆I PP I D-VID
Rg = --------------------------------------------------------------------- where I OCPx = --------------------------- – ------------ + -------------I OC TH ( min )
2
3
3
36/50
L6711
Output voltage monitor and protections
Figure 18. Constant current operation
Ip
e
a
k
V
o
u
t
D
ro
o
pe
ffe
c
t
IM
A
X
IO
C
P
x
T
o
n
M
A
X
T
o
n
M
A
X
a) Maximum current for each phase
14.6
U
V
P
Io
u
t
IM
A
X
,T
O
T
3
·IO
ID
=
1
0
5
µ
A
)
C
P
x(
R
O
O
P
b) Output Characteristic
Inductor sense over current (CS_SEL = SGND)
The device detects an over current when the IINFOx overcome the fixed threshold IOCTH.
Since the device always senses the current across the inductor, the IOCTH crossing will
happen during the HS conduction time: as a consequence of OCP detection, the device will
turn OFF the HS mosfet and turns ON the LS mosfet of that phase until IINFOx re-cross the
threshold or until the next clock cycle. This implies that the device limits the peak of the
inductor current.
In any case, the inductor current won't overcome the IOCPx value and this will represent the
maximum peak value to consider in the OC design.
The device works in Constant-Current, and the output voltage decreases as the load
increase, until the output voltage reaches the UVP threshold. When this threshold is
crossed, all mosfets are turned off, the FAULT pin is driven high and the device stops
working. Cycle the power supply or the OUTEN pin to restart operation.
The transconductance resistor Rg can be designed considering that the device limits the
inductor current ripple peak. Moreover, when designing D-VID systems, the additional
current due to the output filter charge during dynamic VID transitions must be considered.
IOCPx ( max ) ⋅ R SENSE ( max )
I OUT ( OCP ) ∆I PP ID-VID
Rg = --------------------------------------------------------------------- where I OCPx = --------------------------- + ------------ + -------------I OC TH ( min )
2
3
3
37/50
Oscillator
15
L6711
Oscillator
The internal oscillator generates the triangular waveform for the PWM charging and
discharging with a constant current an internal capacitor. The switching frequency for each
channel, FSW, is internally fixed at 150kHz so that the resulting switching frequency at the
load side results in being tripled.
The current delivered to the oscillator is typically 25µA (corresponding to the free running
frequency Fsw=150kHz) and it may be varied using an external resistor (ROSC) connected
between the OSC pin and SGND or VCC (or a fixed voltage greater than 1.24V). Since the OSC
pin is fixed at 1.24V, the frequency is varied proportionally to the current sunk (forced) from (into)
the pin considering the internal gain of 6KHz/µA.
In particular connecting R OSC to SGND the frequency is increased (current is sunk from the
pin), while connecting R OSC to VCC=12V the frequency is reduced (current is forced into the
pin), according to the following relationships:
6
7.422 ⋅ 10
kHz
1.237
R OSC vs. GND: F SW = 150kHz + ---------------------------- ⋅ 6 ----------- = 150kHz + ----------------------------µA
R OSC ( kΩ )
R OSC ( kΩ )
7
6.457 ⋅ 10
kHz
12-1.237
R OSC vs. 12V: F SW = 150kHz + ---------------------------- ⋅ 6 ----------- = 150kHz + ----------------------------µA
R OSC( kΩ )
R OSC ( kΩ )
Maximum programmable switching frequency depends on the Current Reading Method
selected. When reading across LS mosfet, the maximum switching frequency per phase
must be limited to 500kHz to avoid current reading errors causing, as a consequence,
current sharing errors. When reading across the inductor, higher switching frequency can be
approached (device power dissipation must be checked prior to design high switching
frequency systems).
Figure 19. ROSC vs. switching frequency
14000
1000
12000
800
10000
8000
600
6000
400
4000
200
2000
0
25
50
75
100
125
ROSC [kΩ] to 12V vs. Selected FSW [kHz]
38/50
150
0
150
250
350
450
550
650
750
ROSC [kΩ] to SGND vs. Selected FSW [kHz]
850
L6711
16
Driver section
Driver section
The integrated high-current drivers allow using different types of power MOS (also multiple
MOS to reduce the equivalent R dsON), maintaining fast switching transition.
The drivers for the high-side mosfets use BOOTx pins for supply and PHASEx pins for
return. The drivers for the low-side mosfets use VCCDRx pin for supply and PGNDx pin for
return. A minimum voltage of 4.6V at VCCDRx pin is required to start operations of the
device. VCCDRx pins must be connected together.
The controller embodies a sophisticated anti-shoot-through system to minimize low side
body diode conduction time maintaining good efficiency saving the use of Schottky diodes:
when the high-side mosfet turns off, the voltage on its source begins to fall; when the
voltage reaches 2V, the low-side mosfet gate drive is suddenly applied. When the low-side
mosfet turns off, the voltage at LGATEx pin is sensed. When it drops below 1V, the high-side
mosfet gate drive is suddenly applied.
If the current flowing in the inductor is negative, the source of high-side mosfet will never
drop. To allow the turning on of the low-side mosfet even in this case, a watchdog controller
is enabled: if the source of the high-side mosfet doesn't drop for more than 240ns, the low
side mosfet is switched on so allowing the negative current of the inductor to recirculate.
This mechanism allows the system to regulate even if the current is negative.
The BOOTx and VCCDRx pins are separated from IC's power supply (VCC pin) as well as
signal ground (SGND pin) and power ground (PGNDx pin) in order to maximize the
switching noise immunity. The separated supply for the different drivers gives high flexibility
in mosfet choice, allowing the use of logic-level mosfet. Several combination of supply can
be chosen to optimize performance and efficiency of the application.
Power conversion input is also flexible; 5V, 12V bus or any bus that allows the conversion
(See maximum duty cycle limitations) can be chosen freely.
16.1
Power dissipation
Two main terms contribute in the device power dissipation: bias power and drivers' power.
The first one depends on the static consumption of the device through the supply pins and it
is simply quantifiable as follow:
PDC = VCC · (ICC + 3 · ICCDRx + 3 · IBOOTx)
Drivers' power is the power needed by the driver to continuously switch on and off the
external mosfets; it is a function of the switching frequency and total gate charge of the
selected mosfets. It can be quantified considering that the total power PSW dissipated to
switch the mosfets (easy calculable) is dissipated by three main factors: external gate
resistance (when present), intrinsic mosfet resistance and intrinsic driver resistance. This
last term is the important one to be determined to calculate the device power dissipation.
The total power dissipated to switch the mosfets results:
PSW = 3 · (QG_HS · VBOOT + QG_LS · VCCDR) · FSW
External gate resistors helps the device to dissipate the switching power since the same
power P SW will be shared between the internal driver impedance and the external resistor
resulting in a general cooling of the device.It is important to determine the device dissipated
power in order to avoid the junction working beyond its maximum operative temperature.
39/50
Driver section
L6711
Moreover, since the device has an exposed pad to better dissipate the power, also the
thermal resistance between junction and ambient is important.
Figure 16 shows the Switching Power for different kind of mosfets driven.
30 0 0
300 0
25 0 0
250 0
20 0 0
15 0 0
Q G_ H S =3 6 n C
Q G _ LS =9 4 n C
10 0 0
Q G_ H S =7 2 nC
Q G _ LS =1 9 6 n C
500
Q G _H S = 48 n C
Q G _L S =1 2 4 nC
Q G _ H S =2 4 n C
Q G_ LS =6 2 n C
3 00
5 00
700
S w it ch in g F req u e n c y [k H z ] p er P h a s e
RGATE = RGATE_MOSFET = 0
40/50
200 0
150 0
100 0
9 00
Q G_ H S = 48nC
Q G _L S = 124nC
Q G _HS = 24n C
Q G _ LS = 62n C
Q G _HS = 36 nC
Q G _ LS = 9 4nC
Q G _HS = 18n C
Q G _ LS = 47n C
50 0
Q G _ H S =1 8 n C
Q G_ LS =4 7 n C
0
10 0
Co ntro ller D is siap te d P ow er [m W ]
C ontroller Dissiapted Po w er [m W ]
Figure 20. Controller power dissipated (Quiescent + Switching; V CC = V CCDR = VBOOT
= 12V)
Q G _HS = 72n C
Q G _LS = 1 96nC
0
1 00
30 0
500
7 00
900
Sw itc hing Freq uen cy [kH z] p er P hase
RGATE_HS = 2.2Ω; RGATE_LS = 3.3Ω; · RGATE_MOSFET = 1Ω
L6711
17
System control loop compensation
System control loop compensation
The control loop is composed by the Current Sharing control loop and the Average Current
Mode control loop. Each loop gives, with a proper gain, the correction to the PWM in order
to minimize the error in its regulation: the Current Sharing control loop equalize the currents
in the inductors while the Average Current Mode control loop fixes the output voltage equal
to the reference programmed by VID. Figure 21 shows the block diagram of the system
control loop.
Figure 21. Main control loop diagram
00 00 00 00 00 00 00 00 00
000000000
000000000
C
U
R
RE
NT
SH
AR
ING
DU
TYCY
C
LE
C
O
R
RE
C
TIO
N
L1
P
W
M
1
1/5
L2
PW
M
2
1/5
1/5
L3
P
W
M
3
IINFO3
C
o
ER
R
O
RAM
PLIFIER
IINFO1
IINFO2
VID
R
o
IFB
4/5
FB
C
O
M
P
ZF(s)
R
FB
The average current mode control loop is reported in Figure 22. The current information IFB
sourced by the FB pin flows into R FB implementing the dependence of the output voltage
from the read current.
The system can be modeled with an equivalent single phase converter which only
difference is the equivalent inductor L/3 (where each phase has an L inductor).The ACM
control loop gain results (obtained opening the loop after the COMP pin):
PWM ⋅ Z F ( s ) ⋅ ( R D ROOP + Z P ( s ) )
G LOOP ( s ) = – ------------------------------------------------------------------------------------------------------------------ZF ( s )
1
( Z P ( s ) + Z L ( s ) ) ⋅ -------------- + ⎛ 1 + ------------ ⎞ ⋅ R FB
A ( s )⎠
A(s ) ⎝
Where:
●
●
RSENSE is the mosfet RdsON or the Inductor DCR depending on the sensing element
selected;
R SEN SE
R D ROOP = --------------------- ⋅ R FB is the equivalent output resistance determined by droop;
Rg
●
ZP(s) is the impedance resulting by the parallel of the output capacitor (and its ESR)
and the applied load Ro;
●
ZF(s) is the compensation network impedance;
●
ZL(s) is the parallel of the three inductor impedance;
●
A(s) is the error amplifier gain;
41/50
System control loop compensation
●
L6711
4 V IN
PWM = --- ⋅ --------------- is the PWM transfer function where ∆VOSC is the oscillator ramp
5 ∆V osc
amplitude and has a typical value of 3V
Removing the dependence from the Error Amplifier gain, so assuming this gain high
enough, the control loop gain results:
VI N
ZF ( s )
Rs Z P ( s )
4
G LOOP ( s ) = – --- ⋅ ------------------ ⋅ ------------------------------------ ⋅ ⎛ -------- + ---------------⎞
5 ∆V OSC Z P ( s ) + Z L ( s ) ⎝ Rg R FB ⎠
With further simplifications, it results:
VI N
Z F ( s ) Ro + R DROOP
1 + s ⋅ Co ⋅ ( R DROOP //Ro + ESR )
4
G LOOP ( s ) = – --- ⋅ ------------------ ⋅ -------------- ⋅ ------------------------------------- --------------------------------------------------------------------------------------------------------------------------------5 ∆V OSC R FB
RL
R
L
L
2
Ro + ------- s ⋅ Co ⋅ --- + s ⋅ --------------- + Co ⋅ ESR + Co ⋅ ------L- + 1
3
3 ⋅ Ro
3
3
Considering now that in the application of interest it can be assumed that Ro>>R L;
ESR<<Ro and RDROOP<<Ro, it results:
VI N
ZF ( s )
1 + s ⋅ Co ⋅ ( R D ROOP + ESR )
4
G LOOP ( s ) = – --- ⋅ ------------------ ⋅ -------------- ⋅ --------------------------------------------------------------------------------------------------------------------------------5 ∆V OSC R FB
RL
L
L
2
s ⋅ Co ⋅ --- + s ⋅ --------------- + Co ⋅ ESR + Co ⋅ ------- + 1
3
3 ⋅ Ro
3
The ACM control loop gain is designed to obtain a high DC gain to minimize static error and
cross the 0dB axes with a constant -20dB/dec slope with the desired crossover frequency
ωT. Neglecting the effect of ZF(s), the transfer function has one zero and two poles.
Both the poles are fixed once the output filter is designed and the zero is fixed by ESR and
the Droop resistance.
To obtain the desired shape an R F-CF series network is considered for the ZF(s)
implementation. A zero at ωF =1/RFCF is then introduced together with an integrator. This
integrator minimizes the static error while placing the zero in correspondence with the L-C
resonance a simple -20dB/dec shape of the gain is assured).
In fact, considering the usual value for the output filter, the LC resonance results to be at
frequency lower than the above reported zero.
Compensation network can be simply designed placing ωZ=ωLC and imposing the crossover frequency ωT as desired obtaining:
R FB ⋅ ∆V OSC 5
L
R F = ---------------------------------- ⋅ --- ⋅ ω T ⋅ ------------------------------------------------------4
3 ⋅ ( R DROOP + ESR )
VIN
CF
42/50
L
Co ⋅ --3
= -------------------RF
L6711
System control loop compensation
Figure 22. Equivalent Control Loop Gain Block Diagram (left) and Bode Diagram
(right)
IF B
ZF
CF
dB
RF
GLOOP
RFB
VCOM P
K
REF
PW M
L /3
d • V IN
ZF(s)
VOUT
ωLC
ωZ
ωT
ω
Cout
ESR
Rout
⎡4
V
1 ⎤
K = ⎢ ⋅ IN ⋅
⎥
⎣ 5 ∆VOSC RFB ⎦ dB
43/50
Layout guidelines
18
L6711
Layout guidelines
Since the device manages control functions and high-current drivers, layout is one of the
most important things to consider when designing such high current applications.
A good layout solution can generate a benefit in lowering power dissipation on the power
paths, reducing radiation and a proper connection between signal and power ground can
optimize the performance of the control loops.
Integrated power drivers reduce components count and interconnections between control
functions and drivers, reducing the board space.
Here below are listed the main points to focus on when starting a new layout and rules are
suggested for a correct implementation.
18.1
Power connections.
These are the connections where switching and continuous current flows from the input
supply towards the load. The first priority when placing components has to be reserved to
this power section, minimizing the length of each connection and loop as much as possible.
To minimize noise and voltage spikes (EMI and losses) these interconnections must be a
part of a power plane and anyway realized by wide and thick copper traces: loop must be
anyway minimized. The critical components, i.e. the power transistors, must be located as
close as possible one to the other.
Figure 23 shows the details of the power connections involved and the current loops. The
input capacitance (CIN), or at least a portion of the total capacitance needed, has to be
placed close to the power section in order to eliminate the stray inductance generated by
the copper traces. Low ESR and ESL capacitors are preferred.
Use as much VIAs as possible when power traces have to move between different planes
on the PCB: this reduces both parasitic resistance and inductance. Moreover, reproducing
the same high-current trace on more than one PCB layer will reduce the parasitic resistance
associated to that connection.
Connect output bulk capacitor as near as possible to the load, minimizing parasitic
inductance and resistance associated to the copper trace also adding extra decoupling
capacitors along the way to the load when this results in being far from the bulk capacitor
bank.
Figure 23. Power connections and related connections layout guidelines (same for
all phases).
To limit CBOOT Extra-Charge
VIN
UGATEx
PHASEx
BOOTx
CIN
CBOOT
VIN
CIN
PHASEx
L
L
VCC
LGATEx
LOAD
PGNDx
LOAD
SGND
+Vcc
a. PCB power and ground planes areas
44/50
b. PCB small signal components placement
L6711
18.2
Layout guidelines
Power connections related.
Figure 24 shows some small signal components placement.
●
Gate and phase traces must be sized according to the driver RMS current delivered to
the power mosfet. The device robustness allows managing applications with the power
section far from the controller without losing performances. Anyway, when possible, it is
suggested to minimize the distance between controller and power section.
In addition, since the PHASEx pin is the return path for the high side driver, this pin
might be connected directly to the High Side mosfet Source pin to have a proper driving
for this mosfet. For the LS mosfets, the return path is the PGNDx pin: it can be
connected directly to the power ground plane.
●
Bootstrap capacitor must be placed as close as possible to the BOOTx and PHASEx
pins to minimize the loop that is created.
●
Decoupling capacitor from VCC and SGND placed as close as possible to the involved
pins.
●
Decoupling capacitor from VCCDRx and PGNDx placed as close as possible to those
pins. This capacitor sustains the peak currents requested by the low-side mosfet
drivers.
●
Sensible components must be referred to SGND (when present): frequency set-up
resistor ROSC, offset resistor ROFFSET, TC resistor RTC and OVP resistor R OVP.
●
Star grounding: Connect SGND to PGND plane in a single point to avoid that drops due
to the high current delivered causes errors in the device behavior.
●
An additional ceramic capacitor is suggested to place near HS mosfet drain. This helps
in reducing HF noise.
●
VSEN pin filtered vs. SGND helps in reducing noise injection into device.
●
OUTEN pin filtered vs. SGND helps in reducing false trip due to coupled noise: take
care in routing driving net for this pin in order to minimize coupled noise.
●
PHASE pin spikes. Since the HS mosfet switches hardly, heavy voltage spikes can be
observed on the PHASEx pins. If these voltage spikes overcome the max breakdown
voltage of the pin, the device can absorb energy and it can cause damages. The
voltage spikes must be limited by proper layout; by the use of gate resistors, Schottky
diodes in parallel to the low side mosfets and/or snubber network on the low side
mosfets, and cannot overcome 26V, for 20nSec, at FSW = 600kHz.
●
Boot Capacitor Extra Charge. Systems that do not use Schottky diodes might show big
negative spikes on the phase pin. This spike can be limited as well as the positive spike
but has an additional consequence: it causes the bootstrap capacitor to be overcharged. This extra-charge can cause, in the worst case condition of maximum input
voltage and during particular transients, that boot-to-phase voltage overcomes the abs.
max. ratings also causing device failures. It is then suggested in this cases to limit this
extra-charge by adding a small resistor in series to the boot diode (one resistor can be
enough for all the three diodes if placed upstream the diode anode, see Figure 23).
45/50
Layout guidelines
18.3
L6711
Current sense connections.
Remote Buffer: The input connections for this component must be routed as parallel nets
from the FBG/FBR pins to the load in order to compensate losses along the output power
traces and also to avoid the pick-up of any common mode noise. Connecting these pins in
points far from the load will cause a non-optimum load regulation, increasing output
tolerance.
Current Reading: The Rg resistors have to be placed as close as possible to the CSx- and
CSx+ pins in order to limit the noise injection into the device; this is still valid also for the
Rg(RC)-Cg network used when sensing current across the inductor. The PCB traces
connecting these resistors to the reading point must use dedicated nets, routed as parallel
traces in order to avoid the pick-up of any common mode noise.
HS3
R
R
R
R
R
R
R
CS3-
CS2+
CS2-
CS1+
CS1-
C
CS3+
LS 3
LS 2
HS2
HS1
VCCDR
C
To regulated
Output
To Inductor
(or Sense Resistor)
To LS Mosfet
(or Sense Resistor)
V ias to P G N D plane
Vias to P G ND plane
LS 1
Figure 24. Device orientation (left) and sense nets routing (right: red for Lsense,
black for LSsense)
It's also important to avoid any offset in the measurement and, to get a better precision, to
connect the traces as close as possible to the sensing elements. Symmetrical layout is also
suggested.
Small filtering capacitor can be needed between VOUT and SGND on the CSx- line, placed
near the controller, allowing higher layout flexibility in the current sense connection.
46/50
L6711
19
Embedding L6711-based VRDs...
Embedding L6711-based VRDs...
When embedding the VRD into the application, additional care must be taken since the
whole VRD is a switching DC/DC regulator and the most common system in which it has to
work is a digital system such as MB or similar. In fact, latest MB has become faster and
powerful: high speed data bus are more and more common and switching-induced noise
produced by the VRD can affect data integrity if not following additional layout guidelines.
Few easy points must be considered mainly when routing traces in which switching high
currents flow (switching high currents cause voltage spikes across the stray inductance of
the traces causing noise that can affect the near traces):
Keep safe guarding distance between high current switching VRD traces and data buses,
especially if high-speed data bus to minimize noise coupling.
Keep safe guard distance or filter properly when routing bias traces for I/O sub-systems that
must walk near the VRD.
Possible causes of noise can be located in the PHASE connections, Mosfet gate drive and
Input voltage path (from input bulk capacitors and HS drain). Also PGND connections must
be considered if not insisting on a power ground plane. These connections must be carefully
kept far away from noise-sensitive data bus.
Since the generated noise is mainly due to the switching activity of the VRM, noise
emissions depend on how fast the current switch. To reduce noise emission levels, it is also
possible, in addition to the previous guidelines, to reduce the current slope and then to
increase the switching times: this will cause, as a consequence of the higher switching time,
an increase in switching losses that must be considered in the thermal design of the system.
47/50
TQFP48 Mechanical data & package dimensions
20
L6711
TQFP48 Mechanical data & package dimensions
Figure 25. TQFP48 Mechanical data & package dimensions
mm
inch
DIM.
MIN.
TYP.
A
MAX.
MIN.
TYP.
1.20
A1
0.05
A2
0.95
b
0.17
c
0.09
MAX.
0.047
0.15
0.002
1.00
1.05
0.037
0.039
0.22
0.27
0.006
0.008
0.20
0.004
0.006
0.041
0.010
0.008
D
8.80
9.00
9.20
0.346
0.354
0.362
D1
6.80
7.00
7.20
0.268
0.276
0.283
D2
2.00
4.25
0.079
D3
5.50
e
0.50
E
8.80
9.00
E1
6.80
7.00
E2
2.00
E3
L
L1
k
ccc
0.020
9.20
0.346
0.354
7.20
0.268
0.276
4.25
0.079
0.60
0.362
0.283
0.167
Body: 7 x 7 x 1.0mm
0.217
0.50
0.45
0.167
0.217
5.50
e
OUTLINE AND
MECHANICAL DATA
0.019
0.75
1.00
0.018
0.024
0.030
0.039
TQFP48 - EXPOSED PAD
0˚(min.), 3.5˚(typ.), 7˚(max.)
0.08
0.0031
7222746 B
48/50
L6711
21
Revision history
Revision history
Table 8.
Revision History
Date
Revision
Changes
01-Jun-2004
1
First Issue
23-Nov-2004
2
Modificated the Paragraph 18.2 on the page 32/38.
26-Oct-2005
3
Added new paragraph 9.1.2 Warning 2.
18-Apr-2006
4
Updated graphic, Modified Table1
49/50
L6711
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