Data Sheet

Freescale Semiconductor
Technical Data
Document Number: MC34712
Rev. 8.0, 5/2015
3.0 A 1.0 MHz Fully Integrated DDR
Switch-Mode Power Supply
34712
The SMARTMOS 34712 is a highly integrated, space efficient, low cost, single
synchronous buck switching regulator with integrated N-channel power
MOSFETs. It is a high performance point-of-load (PoL) power supply with the
ability to track an external reference voltage.
Its high efficient 3.0 A sink and source capability combined with its voltage
tracking/sequencing ability and tight output regulation, makes it ideal to provide
the termination voltage (VTT) for modern data buses such as Double-Data-Rate
(DDR) memory buses, including but not limited to DDR, DDR2, DDR3, and
DDR4 memories. It also provides a buffered output reference voltage (VREF) to
the memory chipset
The 34712 offers the designer the flexibility of many control, supervisory, and
protection functions to allow for easy implementation of complex designs. It is
housed in a Pb-free, thermally enhanced, and space efficient 24 pin exposed
pad QFN.
Features
SWITCH-MODE POWER SUPPLY
• 50 m integrated N-channel power MOSFETs
• Input voltage operating range from 3.0 V to 6.0 V
• 1% Accurate output voltage, ranging from 0.6 V to 1.35 V
• 1% Accurate buffered reference output voltage
• Programmable switching frequency range from 200 kHz to 1.0 MHz with a
default of 1.0 MHz
• Overcurrent limit and short-circuit protection
• Thermal shutdown
• Output overvoltage and undervoltage detection
• Active low power-good output signal
• Active low standby and shutdown inputs
VIN
(3.0 TO 6.0 V)
EP SUFFIX
98ARL10577D
24-PIN QFN
34712
PVIN
VDDQ
BOOT
VREFIN
VTT
SW
VIN
VOUT
VDDI
FREQ
GND
SD
TERMINATING
RESISTORS
VDDQ
INV
DDR MEMORY
CHIPSET
COMP
VREFOUT
PGND
MCU
STBY
VREF
VIN
DDR MEMORY
CONTROLLER
PG
Figure 1. 34712 Simplified Application Diagram
© Freescale Semiconductor, Inc., 2007-2015. All rights reserved.
MEMORY
BUS
VDDQ
1
Orderable Parts
Table 1. Orderable Part Variations
Part Number
MC34712EP
(1)
Temperature (TA)
Package
-40 °C to 85 °C
24 QFN
Notes
1. To order parts in Tape & Reel, add the R2 suffix to the part number.
34712
2
Analog Integrated Circuit Device Data
Freescale Semiconductor
2
Internal Block Diagram
STBY
Thermal
Monitoring
PG
Internal
Voltage
Regulator
System
Reset
M1
System
Control
Ilimit
Current
Monitoring
Isense
FREQ
SD
M2
VDDI
Discharge
VIN
BOOT
VBOOT
PVIN
Oscillator
Prog.
Frequency
VIN
Buck
Control
Logic
M3
FSW
Gate
Driver
SW
Isense
PGND
M4
VDDI
Bandgap
Regulator
VBG
Ramp
Generator
COMP
PWM
Comparator
+
–
VDDI
COMP
Error
Amplifier
VREFIN
+
–
RREF1
INV
–
+
RREF2
Buffer
M5
Discharge
M6
VOUT
Discharge
GND
VREFOUT
Figure 2. 34712 Simplified Internal Block Diagram
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
3
BOOT
PVIN
PVIN
Pinout Diagram
VIN
3.1
VIN
Pin Connections
VDDI
3
24
23
22
21
20
19
GND
1
18 PVIN
FREQ
2
17
SW
NC
3
16
SW
15
SW
Transparent
Top View
PG
4
STBY
5
14 PGND
SD
6
13
7
8
9
10
11
12
VREFIN
VREFOUT
COMP
INV
VOUT
PGND
PIN 25
PGND
Figure 3. 34712 Pin Connections
3.2
Pin Definitions
A functional description of each pin can be found in the Functional Pin Description section beginning on page 12.
Table 2. 34712 Pin Definitions
Pin Number
Pin Name
Pin Function
Formal Name
Signal Ground
Definition
1
GND
Ground
2
FREQ
Passive
Analog signal ground of IC
3
NC
None
No Connect
No internal connections to this pin
4
PG
Output
Power Good
Active-low (open drain) power-good status reporting pin
5
STBY
Input
Standby
6
SD
Input
Shutdown
7
VREFIN
Input
Voltage Tracking
Reference Input
8
VREFOUT
Output
Reference Voltage
Output
9
COMP
Passive
Compensation
Buck converter external compensation network pin
10
INV
Input
Error Amplifier
Inverting Input
Buck converter error amplifier inverting input pin
11
VOUT
Output
Output Voltage
Discharge FET
Discharge FET drain connection (connect to buck converter output capacitors)
12,13,14
PGND
Ground
Power Ground
Ground return for buck converter and discharge FET
Frequency Adjustment Buck converter switching frequency adjustment pin
Standby mode input control pin
Shutdown mode input control pin
Voltage tracking reference voltage input
Buffered output equal to 1/2 of voltage-tracking reference
34712
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Analog Integrated Circuit Device Data
Freescale Semiconductor
Table 2. 34712 Pin Definitions (continued)
Pin Number
Pin Name
Pin Function
Formal Name
15,16,17
SW
Output
Switching Node
18,19,20
PVIN
Supply
Power-circuit Supply
Input
21
BOOT
Passive
Bootstrap
22,23
VIN
Supply
Logic-circuit Supply
Input
24
VDDI
Passive
Internal Voltage
Regulator
25
GND
Ground
Thermal Pad
Definition
Buck converter power switching node
Buck converter main supply voltage input
Bootstrap switching node (connect to bootstrap capacitor)
Logic circuits supply voltage input
Internal VDD regulator (connect filter capacitor to this pin)
Thermal pad for heat transfer. Connect the thermal pad to the analog ground and
the ground plane for heat sinking.
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
5
4
Electrical Characteristics
4.1
Maximum Ratings
Table 3. Maximum Ratings
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or permanent damage
to the device.
Symbol
Ratings
Value
Unit
Notes
Input Supply Voltage (VIN) Pin
-0.3 to 7.0
V
PVIN
High-side MOSFET Drain Voltage (PVIN) Pin
-0.3 to 7.0
V
VSW
Switching Node (SW) Pin
-0.3 to 7.0
V
BOOT Pin (Referenced to SW Pin)
-0.3 to 7.0
V
-
PG, VOUT, SD, and STBY Pins
-0.3 to 7.0
V
-
VDDI, FREQ, INV, COMP, VREFIN, and VREFOUT Pins
-0.3 to 3.0
V
±3.0
A
(2)
V
(3)
-40 to 85
°C
(4)
-65 to +150
°C
ELECTRICAL RATINGS
VIN
VBOOT - VSW
IOUT
VESD1
VESD2
VESD3
Continuous Output Current
ESD Voltage
• Human Body Model
• Machine Model (MM)
• Device Charge Model (CDM)
±2000
±200
±750
THERMAL RATINGS
TA
Operating Ambient Temperature
TSTG
Storage Temperature
TPPRT
Peak Package Reflow Temperature During Reflow
Note 6
°C
TJ(MAX)
Maximum Junction Temperature
+150
°C
PD
Power Dissipation (TA = 85 °C)
2.9
W
(5),(6)
(7)
Notes
2. Continuous output current capability so long as TJ is TJ(MAX).
3.
ESD testing is performed in accordance with the Human Body Model (HBM) (CZAP = 100 pF, RZAP = 1500 ), the Machine Model (MM) 
(CZAP = 200 pF, RZAP = 0 ), and the Charge Device Model (CDM), Robotic (CZAP = 4.0 pF).
4.
5.
The limiting factor is junction temperature, taking into account power dissipation, thermal resistance, and heatsinking.
Pin soldering temperature limit is for 10 seconds maximum duration. Not designed for immersion soldering. Exceeding these limits may cause
malfunction or permanent damage to the device.
Freescale’s Package Reflow capability meets Pb-free requirements for JEDEC standard J-STD-020C. For Peak Package Reflow Temperature and
Moisture Sensitivity Levels (MSL), Go to www.freescale.com, search by part number [e.g. remove prefixes/suffixes and enter the core ID to view
all orderable parts. (i.e. MC33xxxD enter 33xxx), and review parametrics.
Maximum power dissipation at indicated ambient temperature.
6.
7.
34712
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Analog Integrated Circuit Device Data
Freescale Semiconductor
Table 3. Maximum Ratings (continued)
All voltages are with respect to ground unless otherwise noted. Exceeding these ratings may cause a malfunction or permanent damage
to the device.
Symbol
Ratings
Value
Unit
Notes
THERMAL RESISTANCE (8)
RJA
Thermal Resistance, Junction to Ambient, Single-layer Board (1s)
139
°C/W
(9)
RJMA
Thermal Resistance, Junction to Ambient, Four-layer Board (2s2p)
43
°C/W
(10)
Thermal Resistance, Junction to Board
22
°C/W
(11)
RJB
Notes
8.
9.
10.
11.
The PVIN, SW, and GND pins comprise the main heat conduction paths.
Per SEMI G38-87 and JEDEC JESD51-2 with the single-layer board (JESD51-3) horizontal.
Per JEDEC JESD51-6 with the board (JESD51-7) horizontal. There are no thermal vias connecting the package to the two planes in the board.
Thermal resistance between the device and the printed circuit board per JEDEC JESD51-8. Board temperature is measured on the top surface of
the board near the package.
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
7
4.2
Static Electrical Characteristics
Table 4. Static Electrical Characteristics
Characteristics noted under conditions 3.0 V  VIN  6.0 V, - 40 C  TA  85 C, GND = 0 V, unless otherwise noted. Typical values
noted reflect the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.
Symbol
Characteristic
Min
Typ
Max
Unit
3.0
-
6.0
V
Notes
IC INPUT SUPPLY VOLTAGE (VIN)
VIN
Input Supply Voltage Operating Range
IIN
Input DC Supply Current
• Normal Mode: SD = 1 & STBY = 1, Unloaded Outputs
-
-
25
mA
(12)
Input DC Supply Current
• Standby Mode, SD = 1 & STBY = 0
-
-
15
mA
(12)
Input DC Supply Current
• Shutdown Mode, SD = 0 & STBY = X
-
-
100
µA
(12)
2.35
2.5
2.65
V
IINQ
IINOFF
INTERNAL SUPPLY VOLTAGE OUTPUT (VDDI)
VDDI
Internal Supply Voltage Range
BUCK CONVERTER (PVIN, SW, GND, BOOT, INV, COMP)
PVIN
High-side MOSFET Drain Voltage Range
2.5
-
6.0
V
VOUT
Output Voltage Adjustment Range
0.6
-
1.35
V
(13), (17)
Output Voltage Accuracy
-1.0
-
1.0
%
(13), (14),
(15)
REGLN
Line Regulation
• Normal Operation, VIN = 3.0 to 6.0 V, IOUT = ±3.0 A
-1.0
-
1.0
%
(13)
REGLD
Load Regulation
• Normal Operation, IOUT = -3.0 to 3.0 A
-1.0
-
1.0
%
(13)
VREF
Error Amplifier Common Mode Voltage Range
0.0
-
1.35
V
(13), (16)
VUVR
Output Undervoltage Threshold
-8.0
-
-1.5
%
VOVR
Output Overvoltage Threshold
1.5
-
8.0
%
IOUT
Continuous Output Current
-3.0
-
3.0
A
ILIM
Overcurrent Limit, Sinking and Sourcing
-
4.0
-
A
Short-circuit Current Limit
• (Sourcing and Sinking)
-
6.5
-
A
-
ISHORT
RDS(on)HS
High-side N-CH Power MOSFET (M3) RDS(ON)
• IOUT = 1.0 A, VBOOT - VSW = 3.3 V
10
-
50
m
(13)
RDS(on)LS
Low-side N-CH Power MOSFET (M4) RDS(ON)
• IOUT = 1.0 A, VIN = 3.3 V
10
-
50
m
(13)
Notes
12.
13.
14.
15.
16.
17.
See section Modes of Operation, page 16 has a detailed description of the different operating modes of the 34712
Design information only, this parameter is not production tested.
±1% is assured at room temperature.
Overall output accuracy is directly affected by the accuracy of the external feedback network, 1% feedback resistors are recommended.
The 1% output voltage regulation is only guaranteed for a common mode voltage range greater than or equal to 0.6 V at room temperature.
If a VOUT =0.6 V is desired, make sure PVIN is kept below 3.6 V and the Switching Frequency FSW is lower than 500 kHz to allow enough room
for output regulation
34712
8
Analog Integrated Circuit Device Data
Freescale Semiconductor
Table 4. Static Electrical Characteristics
Characteristics noted under conditions 3.0 V  VIN  6.0 V, - 40 C  TA  85 C, GND = 0 V, unless otherwise noted. Typical values
noted reflect the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.
Symbol
Min
Typ
Max
Unit
M2 RDS(on)
• (VIN = 3.3 V, M2 is on)
1.5
-
4.0

ISW
SW Leakage Current (Standby and Shutdown modes)
-10
-
10
µA
IPVIN
PVIN Pin Leakage Current
• (Standby and Shutdown Modes)
-10
-
10
µA
IINV
INV Pin Leakage Current
-1.0
-
1.0
µA
AEA
Error Amplifier DC Gain
-
150
-
dB
(18)
Error Amplifier Unit Gain Bandwidth
-
3.0
-
MHz
(18)
Error Amplifier Slew Rate
-
7.0
-
V/µs
(18)
-3.0
0.0
3.0
mV
(18)
RDS(on)M2
UGBWEA
SREA
OFFSETEA
Characteristic
Error Amplifier Input Offset
Notes
TSDFET
Thermal Shutdown Threshold
-
170
-
°C
(18)
TSDHYFET
Thermal Shutdown Hysteresis
-
25
-
°C
(18)
0.0
-
VDDI
V
VREFIN External Reference Voltage Range
0.0
-
2.7
V
VREFOUT Buffered Reference Voltage Range
0.0
-
1.35
V
VREFOUT Buffered Reference Voltage Accuracy
-1.0
-
1.0
%
IREFOUT
VREFOUT Buffered Reference Voltage Current Capability
0.0
-
8.0
mA
IREFOUTLIM
VREFOUT Buffered Reference Voltage Overcurrent Limit
-
11
-
mA
RTDR(M6)
VREFOUT Total Discharge Resistance
-
50
-

(18)
RTDR(M5)
VOUT Total Discharge Resistance
-
50
-

(18)
IVOUTLKG
VOUT Pin Leakage Current
• (Standby Mode, VOUT = 3.6 V)
-1.0
-
1.0
µA
OSCILLATOR (FREQ)
VFREQ
Oscillator Frequency Adjusting Reference Voltage Range
TRACKING (VREFIN, VREFOUT, VOUT)
VREFIN
VREFOUT
-
(18)
(19)
CONTROL AND SUPERVISORY (STBY, SD, PG)
VSTBYHI
STBY High Level Input Voltage
2.0
-
-
V
VSTBYLO
STBY Low Level Input Voltage
-
-
0.4
V
RSTBYUP
STBY Pin Internal Pull-up Resistor
1.0
-
2.0
M
VSDHI
SD High Level Input Voltage
2.0
-
-
V
VSDLO
SD Low Level Input Voltage
-
-
0.4
V
RSDUP
SD Pin Internal Pull-up Resistor
1.0
-
2.0
M
VPGLO
PG Low Level Output Voltage
• (IPG = 3.0 mA)
-
-
0.4
V
IPGLKG
PG Pin Leakage Current
• (M1 is off, Pulled up to VIN)
-1.0
-
1.0
µA
Notes
18. Design information only, this parameter is not production tested.
19. The 1 % accuracy is only guaranteed for VREFOUT greater than or equal to 0.6 V at room temperature.
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
9
4.3
Dynamic Electrical Characteristics
Table 5. Dynamic Electrical Characteristics
Characteristics noted under conditions 3.0 V  VIN  6.0 V, - 40 C  TA  85 C, GND = 0 V, unless otherwise noted. Typical values
noted reflect the approximate parameter means at TA = 25 °C under nominal conditions, unless otherwise noted.
Symbol
Characteristic
Min
Typ
Max
Unit
Notes
BUCK CONVERTER (PVIN, SW, GND, BOOT)
tRISE
Switching Node (SW) Rise Time
• (PVIN = 3.3 V, IOUT = ±3.0 A)
-
14
-
ns
(21)
tFALL
Switching Node (SW) Fall Time
• (PVIN = 3.3 V, IOUT = ±3.0 A)
-
20
-
ns
(21)
tOFFMIN
Minimum OFF Time
-
150
-
ns
tONMIN
Minimum ON Time
-
180
-
ns
tSS
Soft Start Duration
• (Normal Mode)
1.3
-
2.6
ms
tLIM
Overcurrent Limit Timer
-
10
-
ms
Overcurrent Limit Retry Timeout Period
80
-
120
ms
Output Undervoltage/Overvoltage Filter Delay Timer
5.0
-
25
µs
tTIMEOUT
tFILTER
OSCILLATOR (FREQ)
FSW
Oscillator Default Switching Frequency
• (FREQ = GND)
-
1.0
-
MHz
FSW
Oscillator Switching Frequency Range
200
-
1000
kHz
(20)
CONTROL AND SUPERVISORY (STBY, SD, PG)
tPGRESET
PG Reset Delay
8.0
-
12
ms
tTIMEOUT
Thermal Shutdown Retry Timeout Period
80
-
120
ms
(21)
Notes
20. Oscillator Frequency tolerance is ±10%.
21. Design information only, this parameter is not production tested.
34712
10
Analog Integrated Circuit Device Data
Freescale Semiconductor
5
Functional Description
5.1
Introduction
In modern microprocessor/memory applications, address commands and control lines require system level termination to a voltage (VTT)
equal to 1/2 the memory supply voltage (VDDQ). Having the termination voltage at midpoint, the power supply insures symmetry for
switching times. Also, a reference voltage (VREF) that is free of any noise or voltage variations is needed for the DDR SDRAM input
receiver, VREF is also equal to 1/2 VDDQ. Varying the VREF voltage effects the setup and hold time of the memory. To comply with DDR
requirements and to obtain best performance, VTT and VREF need to be tightly regulated to track 1/2 VDDQ across voltage, temperature,
and noise margins. VTT should track any variations in the DC VREF value (VTT = VREF +/- 40mV), (See Figure 4) for a DDR system level
diagram.
The 34712 supplies the VTT and a buffered VREF output. To ensure compliance with DDR specifications, the VDDQ line is applied to the
VREFIN pin and divided by 2 internally through a precision resistor divider. This internal voltage is then used as the reference voltage for
the VTT output. The same internal voltage is also buffered to give the VREF voltage at the VREFOUT pin for the application to use without
the need for an external resistor divider. The 34712 provides the tight voltage regulation and power sequencing/tracking required along
with handling the DDR peak transient current requirements. Buffering the VREF output helps its immunity against noise and load changes.
The 34712 utilizes a voltage mode synchronous buck switching converter topology with integrated low RDS(ON) (50 m) N-channel power
MOSFETs to provide a VTT voltage with an accuracy of less than ±2.0%. It has a programmable switching frequency that allows for
flexibility and optimization over the operating conditions and can operate at up to 1.0 MHz to significantly reduce the external components
size and cost. The 34712 can sink and source up to 3.0 A of continuous current. It provides protection against output overcurrent,
overvoltage, undervoltage, and overtemperature conditions. It also protects the system from short -circuit events. It incorporates a powergood output signal to alert the host when a fault occurs.
For boards that support the Suspend-To-RAM (S3) and the Suspend-To-Disk (S5) states, the 34712 offers the STBY and the SD pins
respectively. Pulling any of these pins low, puts the IC in the corresponding state.
By integrating the control/supervisory circuitry along with the Power MOSFET switches for the buck converter into a space-efficient
package, the 34712 offers a complete, small-size, cost-effective, and simple solution to satisfy the needs of DDR memory applications.
Besides DDR memory termination, the 34712 can be used to supply termination for other active buses and graphics card memory. It can
be used in Netcom/Telecom applications like servers. It can also be used in desktop motherboards, game consoles, set top boxes, and
high end high definition TVs.
VDDQ
VTT
VDDQ
RT
RS
VREF
BUS
DDR Memory Controller
DDR Memory Input Receiver
Figure 4. DDR System Level Diagram
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
11
5.2
Functional Pin Description
5.2.1
Reference Voltage Input (VREFIN)
The 34712 tracks 1/2 the voltage applied at this pin.
5.2.2
Reference Voltage Output (VREFOUT)
This is a buffered reference voltage output that is equal to 1/2 VREFIN. It has a 10 mA current drive capability. This output is used as the
VREF voltage rail and should be filtered against any noise. Connect a 0.1 µF, 6.0 V low ESR ceramic filter capacitor between this pin and
the GND pin and between this pin and VDDQ rail. VREFOUT is also used as the reference voltage for the buck converter error amplifier.
5.2.3
Frequency Adjustment Input (FREQ)
The buck converter switching frequency can be adjusted by connecting this pin to an external resistor divider between VDDI and GND
pins. The default switching frequency (FREQ pin connected to ground, GND) is set at 1.0 MHz. Select the switching frequency based on
the PVIN to VTT ratio. Refer to the Switching Frequency Selection section.
5.2.4
Signal Ground (GND)
Analog ground of the IC. Internal analog signals are referenced to this pin voltage.
5.2.5
Internal Supply Voltage Output (VDDI)
This is the output of the internal bias voltage regulator. Connect a 1.0 µF, 6.0 V low ESR ceramic filter capacitor between this pin and the
GND pin. Filtering any spikes on this output is essential to the internal circuitry stable operation.
5.2.6
Output Voltage Discharge Path (VOUT)
Output voltage of the Buck Converter is connected to this pin. it only serves as the output discharge path once the SD signal is asserted.
5.2.7
Error Amplifier Inverting Input (inv)
Buck converter error amplifier inverting input. Connect the VTT voltage directly to this pin.
5.2.8
Compensation Input (COMP)
Buck converter external compensation network connects to this pin. Use a type III compensation network.
5.2.9
Input Supply Voltage (VIN)
IC power supply input voltage. Input filtering is required for the device to operate properly.
5.2.10 Power Ground (PGND)
Buck converter and discharge MOSFETs power ground. It is the source of the buck converter low-side power MOSFET.
5.2.11 Switching Node (SW)
Buck converter switching node. This pin is connected to the output inductor.
34712
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Analog Integrated Circuit Device Data
Freescale Semiconductor
5.2.12 Power Input Voltage (PVIN)
Buck converter power input voltage. This is the drain of the buck converter high-side power MOSFET.
5.2.13 Bootstrap Input (BOOT)
Bootstrap capacitor input pin. Connect a capacitor (as discussed on page 24) between this pin and the SW pin to enhance the gate of the
high-side Power MOSFET during switching.
5.2.14 Shutdown Input (SD)
If this pin is tied to the GND pin, the device is in Shutdown mode. If left unconnected or tied to the VIN pin, the device is in Normal mode.
The pin has an internal pull-up of 1.5 M. This input accepts the S5 (Suspend-To-Disk) control signal.
5.2.15 Standby Input (STBY)
If this pin is tied to the GND pin, the device is in Standby mode. If left unconnected or tied to the VIN pin, the device is in Normal mode.
The pin has an internal pull-up of 1.5 M. This input accepts the S3 (Suspend-To-RAM) control signal.
5.2.16 Power Good Output Signal (PG)
This is an active low open drain output that is used to report the status of the device to a host. This output activates after a successful
power up sequence and stays active as long as the device is in normal operation and is not experiencing any faults. This output activates
after a 10 ms delay and must be pulled up by an external resistor to a supply voltage (e.g.,VIN.).
5.3
Functional Internal Block Description
MC34712 - Functional Block Diagram
Internal Bias Circuits
System Control and Logic
Oscillator
Protection Functions
Control and
Supervisory Functions
Tracking and Sequencing
Buck Converter
Figure 5. 34712 Internal Block Diagram
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
13
5.3.1
Internal Bias Circuits
This block contains all circuits that provide the necessary supply voltages and bias currents for the internal circuitry. It consists of:
• Internal voltage supply regulator: This regulator supplies the VDDI voltage that is used to drive the digital/analog internal circuits. It is
equipped with a Power-On-Reset (POR) circuit that watches for the right regulation levels. External filtering is needed on the VDDI
pin. This block turns off during the shutdown mode.
• Internal bandgap reference voltage: This supplies the reference voltage to some of the internal circuitry.
• Bias circuit: This block generates the bias currents necessary to run all of the blocks in the IC.
5.3.2
System Control and logic
This block is the brain of the IC where the device processes data and reacts to it. Based on the status of the STBY and SD pins, the system
control reacts accordingly and orders the device into the right status. It also takes inputs from all of the monitoring/protection circuits and
initiates power up or power down commands. It communicates with the buck converter to manage the switching operation and protects it
against any faults.
5.3.3
Oscillator
This block generates the clock cycles necessary to run the IC digital blocks. It also generates the buck converter switching frequency. The
switching frequency has a default value of 1.0 MHz and can be programmed by connecting a resistor divider to the FREQ pin, between
VDDI and GND pins (See Figure 1).
5.3.4
Protection Functions
This block contains the following circuits:
• Overcurrent limit and short-circuit detection: This block monitors the output of the buck converter for overcurrent conditions and shortcircuit events and alerts the system control for further command.
• Thermal limit detection: This block monitors the temperature of the device for overheating events. If the temperature rises above the
thermal shutdown threshold, this block alerts the system control for further commands.
• Output overvoltage and undervoltage monitoring: This block monitors the buck converter output voltage to ensure it is within
regulation boundaries. If not, this block alerts the system control for further commands.
5.3.5
Control and Supervisory Functions
This block is used to interface with an outside host. It contains the following circuits:
• Standby control input: An outside host can put the 34712 device into standby mode (S3 or Suspend-To-RAM mode) by sending a
logic “0” to the STBY pin.
• Shutdown control input: An outside host can put the 34712 device into shutdown mode (S5 or Suspend-To-Disk mode) by sending
a logic “0” to the SD pin.
• Power good output signal PG: The 34712 can communicate to an external host that a fault has occurred by releasing the drive on
the PG pin high, allowing the signal/pin to be pulled high by the external pull-up resistor.
5.3.6
Tracking and Sequencing
This block allows the output of the 34712 to track 1/2 the voltage applied at the VREFIN pin. This allows the VREF and VTT voltages to
track 1/2 VDDQ and assures that none of them is higher than VDDQ at any point during normal operating conditions. For power down during
a shutdown (S5) mode, the 34712 uses internal discharge MOSFETs (M5 and M6 on Figure 2) to discharge VTT and VREF respectively.
These discharge MOSFETs are only active during shutdown mode. Using this block along with controlling the SD and STBY pins can offer
the user power sequencing capabilities by controlling when to turn the 34712 outputs on or off.
34712
14
Analog Integrated Circuit Device Data
Freescale Semiconductor
5.3.7
Buck Converter
This block provides the main function of the 34712: DC to DC conversion from an un-regulated input voltage to a regulated output voltage
used by the loads for reliable operation. The buck converter is a high-performance, fixed frequency (externally adjustable), synchronous
buck PWM voltage-mode control. It drives integrated 50 mN-channel power MOSFETs saving board space and enhancing efficiency.
The switching regulator output voltage is adjustable with an accuracy of less than ±2.0% to meet DDR requirements. Its output has the
ability to track 1/2 the voltage applied at the VREFIN pin. The regulator's voltage control loop is compensated using a type III compensation
network, with external components to allow for optimizing the loop compensation, for a wide range of operating conditions. A typical
Bootstrap circuit with an internal PMOS switch is used to provide the voltage necessary to properly enhance the high-side MOSFET gate.
The 34712 is designed to address DDR memory power supplies. The integrated converter has the ability to both sink and source up to
3.0 A of continuous current, making it suitable for bus termination power supplies.
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
15
6
Functional Device Operation
6.1
Operational Modes
SD = 1 &
STBY=0
VIN < 3.0 V
SD = 0 &
STBY=x
Shutdown
VTT = Discharge
VREF = Discharge
PG = 1
Power Off
VTT=OFF
VREF=OFF
PG = 1
Standby
VTT = OFF
VREF = ON
PG = 1
3.0 V<=VIN<=6.0 V
SD = 1 &
STBY=1
SD = 1 &
STBY=1
IOUT>=ISHORT
VTT>VOV
Overvoltage
VTT=ON
VREF=ON
Normal
VTT = ON
VREF=ON
VTT<VOV
Short-circuit
TIMEOUT
Expired
VTT=OFF
VREF=OFF
PG = 1
PG = 0
PG = 1
VTT>VUV
TJ<=145 °C
TIMEOUT Expired
Undervoltage
VTT<VUV
VTT=ON
VREF=ON
Thermal Shutdown
VTT=OFF
VREF=OFF
PG = 1
PG = 1
TIMEOUT
Expired
Over-current
VTT=OFF
VREF=ON
PG = 1
IOUT1>=ILIM1
For>=10 ms
TJ >= 170 °C
Figure 6. Operation Modes Diagram
6.1.1
Modes of Operation
The 34712 has three primary modes of operation:
6.1.1.1
Normal Mode
In normal mode, all functions and outputs are fully operational. To be in this mode, the VIN needs to be within its operating range, both
Shutdown and Standby inputs are high, and no faults are present. This mode consumes the most amount of power.
6.1.1.2
Standby Mode
This mode is predominantly used in Desktop memory solutions where the DDR supply is desired to be ACPI compliant (Advanced
Configuration and Power Interface). When this mode is activated by pulling the STBY pin low, VTT is put in High Z state, IOUT = 0 A, and
VREF stays active. This is the S3 state Suspend-To-Ram or Self Refresh mode and it is the lowest DRAM power state. In this mode, the
DRAM preserves the data. While in this mode, the 34712 consumes less power than in the normal mode, because the buck converter and
most of the internal blocks are disabled.
34712
16
Analog Integrated Circuit Device Data
Freescale Semiconductor
6.1.1.3
Shutdown Mode
In this mode, activated by pulling the SD pin low, the chip is in a shutdown state and the outputs are all disabled and discharged. This is
the S4/S5 power state or Suspend-To-Disk state, where the DRAM loses all of its data content (no power supplied to the DRAM). The
reason to discharge the VTT and VREF lines is to ensure upon exiting, the Shutdown mode that VTT and VREF are lower than VDDQ,
otherwise VTT can remain floating high, and be higher than VDDQ upon powering up. In this mode, the 34712 consumes the least amount
of power since almost all of the internal blocks are disabled.
6.1.2
Start-up Sequence
When power is first applied, the 34712 checks the status of the SD and STBY pins. If the device is in a shutdown mode, no block powers
up and the output does not attempt to ramp. If the device is in a standby mode, only the VDDI internal supply voltage and the bias currents
are established and no further activities occur. Once the SD and STBY pins are released to enable the device, the internal VDDI POR
signal is also released. The rest of the internal blocks is enabled and the buck converter switching frequency value is determined by
reading the FREQ pin. A soft start cycle is then initiated to ramp up the output of the buck converter (VTT). The buck converter error
amplifier uses the voltage on the VREFOUT pin (VREF) as its reference voltage. VREF is equal to 1/2 VDDQ, where VDDQ is applied to the
VREFIN pin. This way, the 34712 assures that VREF and VTT voltages track 1/2 VDDQ to meet DDR requirements.
Soft start is used to prevent the output voltage from overshooting during startup. At initial startup, the output capacitor is at zero volts; VOUT
= 0 V. Therefore, the voltage across the inductor is PVIN during the capacitor charge phase which creates a very sharp di/dt ramp. Allowing
the inductor current to rise too high can result in a large difference between the charging current and the actual load current that can result
in an undesired voltage spike once the capacitor is fully charged. The soft start is active each time the IC goes out of standby or shutdown
mode, power is recycled, or after a fault retry.
To fully take advantage of soft starting, it is recommended not to enable the 34712 output before introducing VDDQ on the VREFIN pin.
If this happens after a soft start cycle expires and the VREFIN voltage has a high dv/dt, the output naturally tracks it immediately and ramp
up with a fast dv/dt itself and this defeats the purpose of soft starting. For reliable operation, it is best to have the VDDQ voltage available
before enabling the output of the 34712.
After a successful start-up cycle where the device is enabled, no faults have occurred, and the output voltage has reached its regulation
point, the 34712 pulls the power good output signal low after a 10 ms reset delay, to indicate to the host the device is in normal operation.
6.2
Protection and Diagnostic Features
The 34712 monitors the application for several fault conditions to protect the load from overstress. The reaction of the IC to these faults
ranges from turning off the outputs to just alerting the host that something is wrong. In the following paragraphs, each fault condition is
explained:
6.2.1
Output Overvoltage
An overvoltage condition occurs once the output voltage goes higher than the rising overvoltage threshold (VOVR). In this case, the power
good output signal is pulled high, alerting the host that a fault is present, but the VTT and VREF outputs stays active. To avoid erroneous
overvoltage conditions, a 20 µs filter is implemented. The buck converter uses its feedback loop to attempt to correct the fault. Once the
output voltage falls below the falling overvoltage threshold (VOVF), the fault is cleared and the power good output signal is pulled low, the
device is back in normal operation.
6.2.2
Output Undervoltage
An undervoltage condition occurs once the output voltage falls below the falling undervoltage threshold (VUVF). In this case, the power
good output signal is pulled high, alerting the host that a fault is present, but the VTT and VREF outputs stays active. To avoid erroneous
undervoltage conditions, a 20 µs filter is implemented. The buck converter uses its feedback loop to attempt to correct the fault. Once the
output voltage rises above the rising undervoltage threshold (VUVR), the fault is cleared and the power good output signal is pulled low,
the device is back in normal operation.
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
17
6.2.3
Output Overcurrent
This block detects overcurrent in the Power MOSFETs of the buck converter. It is comprised of a sense MOSFET and a comparator. The
sense MOSFET acts as a current detecting device by sampling a ratio of the load current. That sample is compared via the comparator
with an internal reference to determine if the output is in over-current or not. If the peak current in the output inductor reaches the over
current limit (ILIM), the converter starts a cycle-by-cycle operation to limit the current, and a 10 ms over-current limit timer (tLIM) starts. The
converter stays in this mode of operation until one of the following occurs:
• The current is reduced back to the normal level before tLIM expires, and in this case normal operation is regained.
• tLIM expires without regaining normal operation, at which point the device turns off the output and the power good output signal is
pulled high. At the end of a timeout period of 100 ms (tTIMEOUT), the device attempts another soft start cycle.
• The device reaches the thermal shutdown limit (TSDFET) and turns off the output. The power good output signal is pulled high.
6.2.4
Short-circuit Current Limit
This block uses the same current detection mechanism as the overcurrent limit detection block. If the load current reaches the ISHORT
value, the device reacts by shutting down the output immediately. This is necessary to prevent damage in case of a permanent short circuit.
Then, at the end of a timeout period of 100 ms (tTIMEOUT), the device attempts another soft start cycle.
6.2.5
Thermal Shutdown
Thermal limit detection block monitors the temperature of the device and protects against excessive heating. If the temperature reaches
the thermal shutdown threshold (TSDFET), the converter output switches off and the power good output signal indicates a fault by pulling
high. The device stays in this state until the temperature has decreased by the hysteresis value and then after a timeout period (TTIMEOUT)
of 100 ms, the device retries automatically and the output goes through a soft start cycle. If successful normal operation is regained, the
power good output signal is asserted low.
34712
18
Analog Integrated Circuit Device Data
Freescale Semiconductor
Typical Applications
BOOT
VIN
Compensation Network
C15
0.1 F
VDDI
VOUT
R2
12.7 k_nopop
x
4
PG
PGOOD LED
VMASTER
VMASTER
R8
10 k_nopop
5
STBY
VIN
6
SD
R7
1k
VREFIN
VREFIN
D1
LED
R9
10 k_nopop
3
NC
PVIN
VIN
GND
GND
VMASTER
VOUT
Optional nopop
3
2
1
3
2
1
PVIN
PVIN
SW
PG
STBY
SD
GND
7
8
9
C13
0.1 F
10
11
18
17
16
SW
SW
15
14
GND
13
GND
12
INV
C11
0.1 F
COMP
VOUT
Jumpers
4.7_nopop
R16
SW
MC34712
I/O Signals
C16
0.1 F
PVIN
SW
VREFOUT
C17
10 F
19
FREQ
LED
VIN
BOOT
VIN
SGND
C12
0.1 F
VIN Capacitors
20
GND
2
VIN
1
R11
10 k
21
INV
C19
1.9 nF
R1
20 k
22
COMP
R14
300
23
VREFOUT
R15
15 k
C20
1.0 nF
24
VDDI
FREQ
C18
0.02 pF
PVIN
C14
0.1 F
VREFIN
R12
10 k_nopop
INV
COMP
PVIN
SW
VOUT
7
J2
J3
PVIN
VMASTER
STBY_nopop
LED
1
2
1
2
1
3
5
7
9
J1
2
4
6
8
10
VREFIN
PG
STBY
SD
CON10A
SD
VDDI
Buck Converter
FREQ
R6
POT_50 k_nopop
SW
PVIN Capacitors
D3
PMEG2010EA
_nopop
L1
1.5 H
VOUT2
VOUT1
VOUT
R3
4.7_nopop
C7
C6
C8
C9
100 F 100 F
100 F
1 nF_nopop
PVIN
C1
0.1 F
C2
1 F
C3
C4
C5
100 F 100 F 100 F
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
19
7.1
Component Selection
7.1.1
Switching Frequency Selection
The switching frequency defaults to a value of 1.0 MHz when the FREQ pin is grounded, and 200 kHz when the FREQ pin is connected
to VDDI. Intermediate switching frequencies can be obtained by connecting an external resistor divider to the FREQ pin. Table 6 shows
the resulting switching frequency versus FREQ pin voltage. To ensure the VTT (VOUT) regulation, frequency should be selected such that
the buck regulator switch ON time is higher than 300 ns. For example, for a 3.3 VIN bus and 0.6 V VTT, choose fSW of 466 kHz.
Table 6. Switching Frequency Adjustment
FREQUENCY
VOLTAGE APPLIED TO PIN FREQ
200
2.341 – 2.500
253
2.185 - 2.340
307
2.029 - 2.184
360
1.873 - 2.028
413
1.717 – 1.872
466
1.561 – 1.716
520
1.405 - 1.560
573
1.249 - 1.404
627
1.093 - 1.248
680
0.936 - 1.092
733
0.781 - 0.936
787
0.625 - 0.780
840
0.469 - 0.624
893
0.313 - 0.468
947
0.157 - 0.312
1000
0.000 - 0.156
RFQH
RFQL
VDDI
FREQ
GND
Figure 7. Resistor Divider for Frequency Adjustment
34712
20
Analog Integrated Circuit Device Data
Freescale Semiconductor
7.2
Selection of the Inductor
Inductor calculation is straight forward, being
where,
Maximum OFF time percentage
Switching period.
Drain – to – source resistance of FET
Winding resistance of Inductor
Output current ripple.
7.3
Output Filter Capacitor
For the output capacitor, the following considerations are more important than the actual capacitance value, the physical size, the ESR
and the voltage rating:
Transient Response percentage, TR_%
(Use a recommended value of 2 to 4% to assure a good transient response.)
Maximum Transient Voltage, TR_v_dip = Vo*TR_%
Maximum current step,
Inductor Current rise time,
where,
D_max = Maximum ON time percentage.
IO = Rated output current.
Vin_min = Minimum input voltage at PVIN
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
21
As a result, it is possible to calculate
In order to find the maximum allowed ESR,
The effects of the ESR is often neglected by the designers and may present a hidden danger to the ultimate supply stability. Poor quality
capacitors have widely disparate ESR value, which can make the closed loop response inconsistent.
Io
Io_step
Current
response
dt_I_rise
Worst case
assumption
Figure 8. Transient Parameters
7.3.1
Type III Compensation Network
Power supplies are desired to offer accurate and tight regulation output voltages. To accomplish this requires a high DC gain, but with high
gain comes the possibility of instability. The purpose of adding compensation to the internal error amplifier is to counteract some of the
gains and phases contained in the control-to-output transfer function that could jeopardized the stability of the power supply. The Type III
compensation network used for 34712 comprises two poles (one integrator and one high frequency pole to cancel the zero generated from
the ESR of the output capacitor) and two zeros to cancel the two poles generated from the LC filter as shown in Figure 9.
Gate
Driver
FSW
SW
PWM
Comparitor
+
–
Ramp
Generator
L
VOUT
RS
Error
Amplifier
–
+
VREFOUT
RO CO
CS
INV
RF
COMP
CX
CF
34712
Figure 9. Type III Compensation Network
34712
22
Analog Integrated Circuit Device Data
Freescale Semiconductor
Consider the crossover frequency, FCROSS, of the open loop gain at one-tenth of the switching frequency, FSW.
Then,
10
F CROSS = ---------------------------2  R O C F

10
C F = --------------------------------------2  R O F CROSS
where RO is a user selected resistor. Knowing the LC frequency, it can be obtained the values of RF and CS:
This gives as a result,
&
Calculate Rs by placing the Pole 1 at the ESR zero frequency:

Equating the Pole 2 to 5 times the Crossover Frequency to achieve a faster response and a proper phase margin,
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
23
5  F CROSS = F
1
---------------------------------------P2 =
CF CX
2  R F --------------------CF + CX

7.3.2
Bootstrap Capacitor
The bootstrap capacitor is needed to supply the gate voltage for the high-side MOSFET. This N-Channel MOSFET needs a voltage
difference between its gate and source to be able to turn on. The high-side MOSFET source is the SW node, so it is not ground and it is
floating and moving in voltage, so it cannot just apply a voltage directly to the gate of the high-side that is referenced to ground, a voltage
referenced to the SW node is needed. That is why the bootstrap capacitor is needed for. This capacitor charges during the high-side off
time, since the low-side is on during that time, so the SW node and the bottom of the bootstrap capacitor is connected to ground and the
top of the capacitor is connected to a voltage source, so the capacitor charges up to that voltage source (say 5.0 V). Now when the lowside MOSFET switches off and the high-side MOSFET switches on, the SW nodes rises up to Vin, and the voltage on the boot pin is VCAP
+ VIN. So the gate of the high-side has VCAP across it and it is able to stay enhanced. A 0.1 F capacitor is a good value for this bootstrap
element.
7.3.3
Layout Guidelines
The layout of any switching regulator requires careful consideration. First, there are high di/dt signals present, and the traces carrying
these signals need to be kept as short and as wide as possible to minimize the trace inductance, and therefore reduce the voltage spikes
they can create. To do this, an understanding of the major current carrying loops is important. See Figure 10. These loops, and their
associated components, should be placed in such a way as to minimize the loop size to prevent coupling to other parts of the circuit. Also,
the current carrying power traces and their associated return traces should run adjacent to one another, to minimize the amount of noise
coupling. If sensitive traces must cross the current carrying traces, they should be made perpendicular to one another to reduce field
interaction.
Second, small signal components which connect to sensitive nodes need consideration. The critical small signal components are the ones
associated with the feedback circuit. The high impedance input of the error amp is especially sensitive to noise, and the feedback and
compensation components should be placed as far from the switch node, and as close to the input of the error amplifier as possible. Other
critical small signal components include the bypass capacitors for VIN, VREFIN, and VDDI. Locate the bypass capacitors as close to the
pin as possible.
The use of a multi-layer printed circuit board is recommended. Dedicate one layer, usually the layer under the top layer, as a ground plane.
Make all critical component ground connections with vias to this layer. Make sure that the power ground, PGND, is connected directly to
the ground plane and not routed through the thermal pad or analog ground. Dedicate another layer as a power plane and split this plane
into local areas for common voltage nets.
The IC input supply (VIN) should be connected with a dedicated trace to the input supply. This helps prevent noise from the Buck
Regulator's power input (PVIN) from injecting switching noise into the IC’s analog circuitry.
In order to effectively transfer heat from the top layer to the ground plane and other layers of the printed circuit board, thermal vias need
to be used in the thermal pad design. It is recommended that 5 to 9 vias be spaced evenly and have a finished diameter of 0.3 mm.
VIN1
VIN2PVIN
and 3
Loop Curr ent
HS ON
HS
Loop Curr ent
HS ON
Buck Converter
SW3
SW2 and
SW1
SD
HS
Loop
Current
SD ON
LS
Loop
Current
LS ON
GND2
and 3
PGND
Figure 10. Current Loops
34712
24
Analog Integrated Circuit Device Data
Freescale Semiconductor
8
Packaging
8.1
Packaging Dimensions
Package dimensions are provided in package drawings. To find the most current package outline drawing, go to www.freescale.com and
perform a keyword search for the drawing’s document number.
Package
Suffix
24-Pin QFN
EP
Package Outline Drawing Number
98ARL10577D
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
25
34712
26
Analog Integrated Circuit Device Data
Freescale Semiconductor
34712
Analog Integrated Circuit Device Data
Freescale Semiconductor
27
9
Revision History
REVISION
DATE
DESCRIPTION OF CHANGES
1.0
2/2006
2.0
11/2006
3.0
2/2007
4.0
5/2007
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
5.0
12/2008
•
•
•
Pre-release version
Implemented Revision History page
Initial release
Converted format from Market Assessment to Product Preview
Major updates to the data, form, and style
Replaced all electrolytic capacitors with ceramic ones in Figure 1
Deleted Deadtime in Dynamic Electrical Characteristics
Moved Figures 8 ahead of Type III Compensation Network
Changed Features from 2% to 1%
Changed 34712 Simplified Application Diagram
Removed Machine Model in Maximum Ratings
Added minimum limits to Input DC Supply Current Normal mode, Input DC Supply Current Standby mode, and Input
DC Supply Current Shutdown mode
Added High-side MOSFET Drain Voltage Range
Changed Output Voltage Accuracy
Changed Short-circuit Current Limit
Changed High-side N-CH Power MOSFET (M3) RDS(ON) and Low-side N-CH Power MOSFET (M4) RDS(ON)
Changed M2 RDS(on)
Changed PVIN Pin Leakage Current
Changed VREFOUT Buffered Reference Voltage Accuracy, VREFOUT Buffered Reference Voltage Current
Capability, and VREFOUT Buffered Reference Voltage Overcurrent Limit
Changed STBY Pin Internal Pull-up Resistor and SD Pin Internal Pull-up Resistor
Changed Soft Start Duration, Overcurrent Limit Retry Timeout Period, and Output Undervoltage/Overvoltage Filter
Delay Timer
Changed Oscillator Default Switching Frequency
Changed PG Reset Delay and Thermal Shutdown Retry Timeout Period
Changed drawings in Typical Applications
Changed drawing in Type III Compensation Network
Removed PC34712EP/R2 from the ordering information and added MC34712EP/R2
Changed the data sheet status to Advance Information
Made changes to Switching Node (SW) Pin, BOOT Pin (Referenced to SW Pin), Output Undervoltage Threshold,
Output Overvoltage Threshold, High-side N-CH Power MOSFET (M3) RDS(ON), Low-side N-CH Power MOSFET
(M4) RDS(ON), Device Charge Model (CDM)
Added Machine Model (MM), SW Leakage Current (Standby and Shutdown modes), Error Amplifier DC Gain, Error
Amplifier Unit Gain Bandwidth, Error Amplifier Slew Rate, Error Amplifier Input Offset
Added pin 25 to Figure 3 and the 34712 Pin Definitions
Added the section Layout Guidelines
6.0
4/2012
• Changed typical for Minimum ON Time on page 10
7.0
3/2015
• Added note (17) to Static Electrical Characteristics
8.0
5/2015
• Minimum output voltage extended to 0.6 V
34712
28
Analog Integrated Circuit Device Data
Freescale Semiconductor
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© 2015 Freescale Semiconductor, Inc.
Document Number: MC34712
Rev. 8.0
5/2015