SEMTECH SC2615

SC2615
Complete DDR Power Solution
POWER MANAGEMENT
Description
Features
The SC2615 is a fully integrated, Three in One, Linear
DDR power solution providing power for the VDDQ and
the VTT rails. The SC2615 completely adheres to the
ACPI sleep state power requirements per Intel R
motherboard specifications. A linear regulator controller
provides the high current of the VDDQ during S0, via an
external Power MOSFET, while an internal 1.8A (min) sink/
source regulator supplies the termination voltage.
‹ Single chip solution adheres to ACPI sleep state
requirements using BF_CUT
UVLO on 3.3V and 12V
Internal S3 state LDO for VDDQ supplies 650 mA
Dual thermal shutdown
Fast transient response
Internal VTT regulator Sinks and Sources 1.8A
(Min)
‹ Power good output
‹ 18 pin MLP package
‹
‹
‹
‹
‹
In addition to these two blocks, an Internal LDO provides
VDDQ power during S3, capable of sourcing 650 mA.
The SC2615 uses IntelR defined Latched BF_CUT signal
which is also used to drive the external Blocking MOSFET.
Additional logic, two UVLOs and three thermal shutdown
circuits assure reliability of this single chip DDR power
solution. A Power Good Output indicates the rails are in
regulation.
Applications
‹ DDR power solution for IntelR motherboard
applications
‹ High speed data line termination
‹ Graphic cards
‹ Disk drives
A Soft Start/Enable pin assures proper startup and allows
external shutdown control. The MLP package provides
excellent thermal impedance while keeping a small
footprint.
Typical Application Circuit
12V
5V
5V STBY
Cin
1uF
4
BF_CUT
BF_CUT
11
PWRGD
PWRGD
10
18
17
0.1uF
12
3
3.3VCC
5VSBY
TG
BF_CUT
NC
PGOOD
NC
SS/EN
VDDQSTBY
NC
AGND
LGND
VTTSNS
VDDQIN
FB
VTT
VTT
9
VDDQ
15
14
Cout
13
7
8
1
6
5
VTT
19
2
SC2615
12VCC
HSINKPAD
16
Revision 2, April 2003
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SC2615
POWER MANAGEMENT
Absolute Maximum Ratings
Exceeding the specifications below may result in permanent damage to the device, or device malfunction. Operation outside of the parameters specified
in the Electrical Characteristics section is not implied.
Parameter
Symbol
Maximum
Units
Input Supply Voltage, 3.3VCC
VCC3
7
V
Input Supply Voltage, 12VCC
V C C 12
15
V
VTT Output Current
IO(VTT)
±3
A
5V Standby Input Voltage
V 5S B
7
V
I/O
5VSTBY +0.3, GND -0.3
V
±0.3
V
Inputs and Outputs
AGND to LGND
Operating Ambient Temperature Range
TA
0 to 70
°C
Operating Junction Temperature
TJ
125
°C
θJA
25
°C/W
θJC
4
°C/W
Storage Temperature
TSTG
-65 to 150
°C
Lead Temperature (Soldering) 10seconds
TLEAD
300
°C
ESD Rating (Human Body Model)
ESD
2
kV
Thermal Resistance Junction to Ambient
Thermal Resistance Junction to Case
(1)
(1)
Electrical Characteristics
Unless specified: TA = 0 to 70°C, VCC12 = 12V, VCC3 = 3.3V, 5VSTBY = 5V.
Parameter
Symbol
Conditions
Min
Typ
Max
Units
3.3V Supply Voltage
VCC3.3
3.0
3.3
3.6
V
12V Supply Voltage
V C C 12
10.8
12
13.2
V
5V Standby Voltage
V 5S B
4.5
5
5.5
V
5V STBY Input Quiescent
Current
S0
IQ(STBY)
2.4
BF_CUT Threshold
mA
TTL
12V Under Voltage Lockout
UVLO12
7
8.2
10
V
3.3V Under Voltage Lockout
UVLO3.3
2.4
2.9
3.0
V
Feedback Reference
Feedback Current
1.25
VREF
IFB
V
2
µA
5
mA
5V STBY in S3 Current
IQ(STBY)
2
SS/EN Shutdown Threshold
VEN(TH)
0.2
V
150
°C
Thermal Shutdown
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SC2615
POWER MANAGEMENT
Electrical Characteristics (Cont.)
Unless specified: TA = 0 to 70°C, VCC12 = 12V, VCC3 = 3.3V, 5VSTBY = 5V.
Parameter
Symbol
Conditions
Min
Typ
Max
Units
VOUT
DDR1
2.450
2.5
2.550
V
DDR2
1.764
1.8
1.836
V
VDDQ Linear
Output Voltage
Soft Start Current
ISS
Overcurrent Trip Voltage
VTRIP
Error Amplifier Bandwidth
BW
Load Regulation
Error Amplifier Gain
25
50
60
%
MHz
2
AOL
Power Good High Leakage
70
5
Tjmax<125°C
Power Good Low
µA
75
%
db
1mA sink
50
400
mV
5V
0.1
2
µA
S TB Y LD O
Output Current
S3
Load Regulation
650
mA
Tjmax<125°C
2
%
V TT LD O
Source and Sink Currents(2)
ITT
1.8
2.0
Load Regulation
Error Amplifier Gain
A
2.5
GEA
75
%
db
Notes:
(1) Mounting considerations: The thermal copper pad on bottom of device must be soldered to a solid copper
area, of 1 inch * 1 inch (min.) with multiple vias under the device to achieve specified θ JA and θ JC,
(See recommended land pattern).
(2) This limit indicates that the regulator has a current limit threshold that is greater than the rated Minimum
current. The rated current can only be achieved if the Absolute Maximum Junctions temperatures are not
violated. The amount of heatsinking determines the maximum usable VTT current.
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SC2615
POWER MANAGEMENT
Pin Configuration
Ordering Information
Top View
Part Numbers
P ackag e
SC2615MLTR(1)
MLP-18
Notes:
(1) Only available in tape and reel packaging. A reel
contains 3000 devices.
(MLP-18)
Pin Descriptions
Pin #
Pin Name
1
FB
Feedback for the VDDQ and standby LDO.
2
VTTSNS
VTT LDO feedback and remote sense input.
3
LGND
4
5VSTBY
5,6
VTT
7
VDDQSTBY
8
VDDQIN
VDDQ supply input to VTT regulator.
9
3.3VCC
Input Power rail.
10
PGOOD
VDDQ regulator power good indicator.
11
BF_CUT
BF_CUT signal from "Glue" chip. Controls the BF_CUT MOSFET during S3.
12
AGND
Analog ground.
13, 14
NC
No Connection.
15
TG
Regulator control for VDDQ output MOSFET.
16
12V C C
17
NC
18
SS/EN
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Pin Function
VTT regulator ground.
IC VCC from 5V standby.
VTT regulator output. A 0.1µF - 1µF ceramic capacitor must be placed less than
0.25 inch from VTT pins to Ground.
VDDQ "suspend to memory" regulator output.
Supply for VDDQ control.
No connection.
Soft start/Enable control.
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SC2615
POWER MANAGEMENT
Block Diagram
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SC2615
POWER MANAGEMENT
Timing Diagram
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SC2615
POWER MANAGEMENT
Applications Information
Description
regulator supplies the “Suspend To RAM” current of 650
mA (max) to maintain the information in memory while in
standby mode. Since the Memory read/write cycles are
suspended during S3, the VTT termination voltage is not
needed and is tri-stated during S3. Once BF_CUT goes
low, signifying S0 mode, the VDDQ supply recovers and
takes control of the VDDQ bus.
The memory read-write cycles start after the Silver box
POWER_OK signal goes high. The Silver-Box supply
POWER_OK signal goes high when all the voltages are
within a tight tolerance of the nominal voltage (typically
with 1-2%). Thus, the transition from S3 to S0 does not
cause a drop out in VDDQ voltage, since the higher VDDQ
currents follow the transition of POWER_OK signal from
the input Silver Box supply. The External VDDQ MOSFET,
which is capable of supplying the higher current, is
activated from the UVLO transition of the Input Rails,
which occur much earlier. Thus the External MOSFET will
be activated in time for the Memory’s Active state.
The Semtech SC2615 DDR power supply controller is
the latest and most complete linear regulator, providing
the necessary functions to comply with the BF_CUT signal
generated by IntelR Motherboards. The BF_CUT input
signal is generated via an External “Glue Chip” and can
be logically defined as :
BF_CUT=S0 .NAND.P_OK
Where S0 is the “Motherboard Active signal”. When S0
is logic “Low”, the motherboard is in S3 mode. The
Latched BF_CUT signal is the input to the SC2615
controller, and is generated by using the S5 signal. All
references made to BF_CUT are referring to the latched
signal.
The BF_CUT signal is inverted to externally drive a
Back_Feed_Cut MOSEFT, used to prevent current flow
from the VDDQ supply back to the 3.3V supply during S3
state. VDDQ supply and the VTT termination voltages
are supplied to the DDR SDRAM databus during S0
(normal operation) state. During S0, VDDQ is supplied
via the an external pass MOSFET from the 3.3V rail ,
sourcing high output currents to the VDD bus as well as
supplying the termination supply current.
The VTT termination voltage is an internal sink/source
linear regulator, which during S0 state receives its power
from the VDDQ bus. It is capable of sourcing and sinking
1.8 Amps (Min) . The current limit on this pin is set to 3
Amps (typical). The current handling capacity of this pin
depends upon the amount of heat the PC board can sink
from the SC2615 thermal pad. (See mounting
instructions). The PC board layout must take into
consideration the high current paths, and ground returns
for both the VDDQ and VTT supply pins. VTT, LGND, VDDQ,
3.3VCC traces must also be routed using wide traces to
minimize power loss and heat in these traces, based on
the current handling requirements.
Initial Conditions
When the S5 and S3 go high (BF_CUT goes low) for the
first time, the VDDQ is supplied via the external MOSFET,
thus removing the burden of charging the output
capacitors via the internal linear VDDQ regulator.
Reset/restart
The SS/EN pin must be pulled low and high again to restart
the SC2615. This can be achieved by cycling the input
supplies, 3.3VCC/12VCC. There is a 50mV Hysteresis
on the UVLO threshold. When the rails are near the UVLO
thresholds, it is possible for noise to trigger the UVLO.
Since the reference for the UVLO threshold is derived
from the 5VSBY voltage, sufficient bypassing of the
5VSBY improves noise immunity of the UVLO circuit.
The Short Circuit Protection function is disabled when
any of the input rails are below their respective UVLO
thresholds.
S3 and S5 States
Back-feeding the Input Supply
The operation of the VDDQ and VTT supplies is governed
by the internal sequencing logic in strict adherence with
IntelTM specifications with regards to the BF_CUT signal.
The timing diagram demonstrates the state of the
controller, and each of the VDDQ and VTT supplies during
S3 and S5 transitions. When S3 is low, the VDDQ internal
When in S3 state, VDDQ is supplied by the internal linear
regulator. Current can flow back from the VDDQ supply
through the body diode of the Top MOSFET to the 3.3V
input supply from the Silver Box, which is off during this
state. This in turn shorts out the VDDQ bus and is not
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SC2615
POWER MANAGEMENT
Applications Information (Cont.)
desirable.
A MOSFET in series with the top pass MOSFET (See typical
application circuit) must block this reverse current during
S3. This MOSFET can be driven from the inverted BF_CUT
signal. By removing the gate drive for this series MOSFET,
the current path from the VDDQ supply back into the
input power source is removed. This MOSFET is enhanced
during S0 state.
Short Circuit Protection
Short Circuit Protection is implemented by sensing the
VDDQ voltage. If the SS/EN pin has risen above 1.25V
(i.e. the controller has completed the startup cycle), and
the output falls to 60% of its nominal voltage, as sensed
by the FB pin, the TG pin is latched off and the linear
controllers shut down. To recover from this condition,
either the power rails have to be recycled, or the SS/EN
pin must be pulled low and released to restart controller
operation. The short circuit protection function is disabled
when any of the input rails are below their respective
UVLO thresholds.
Thermal Shutdown
There are three independent Thermal Shutdown
protection circuits in the SC2615, the VDDQ linear
regulator the VTT source regulator, and the VTT sink
regulator. If any of the three regulators’ temperature
rises above the threshold, that regulator will turn off
independently, until the temperature falls below the
thermal shutdown limit.
Power Good
An open collector output provides indication that the
VDDQ is regulating. This is accomplished by monitoring
the SS/EN pin. When the voltage on this pin has risen
above 1.0V, the PGOOD goes high (open). When BF_CUT
goes high (standby), the 5V and 12V rails go low, and the
SS/EN also goes low. Subsequently, PWRGD will also go
low, and stays low until the 3.3V and/or 12V rails are
recycled and rise above their respective UVLO thresholds.
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SC2615
POWER MANAGEMENT
Typical Characteristics
SC2615 DDR controller’s timing : BF_CUT generated from S3 and P_OK
Ch1: S3 signal to Silverbox
Ch2: Power_OK from Silverbox
Ch3: BF_CUT(NOT)=S3.AND.P_OK
Ch4: SS/EN
SC2615 DDR controller’s timing : VDDQ and VTT vs. BF_CUT
Ch3: VTT @ 650 mA
Ch1: BF_CUT (NOT)
Ch4: PGOOD output
Ch2: VDDQ with 2.5V offset, @ 650mA
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SC2615
POWER MANAGEMENT
Typical Characteristics (Cont.)
SC2615 DDR controller’s timing : Power Good vs. SS/EN pin
Ch1: BF_CUT (NOT)
Ch2: VDDQ with 2.5V offset, @ 650mA
Ch3: VTT @ 650 mA
Ch4: PGOOD output
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SC2615
POWER MANAGEMENT
Mounting Considerations
Description
Solder Mask
The MLP18 is a leadless package whose electrical
connections are made by lands on the bottom surface
of the component. These lands are soldered directly to
the PC board. The MLP has an exposed die attach pad,
which enhances the thermal and electrical characteristics
enabling high power applications. Power handling capability
of the MLP package is typically >2x the power of other
SMT packages. In order to take full advantage of this
feature the exposed pad must be physically connected
to the PCB substrate with solder.
Design the solder mask around all pads on each side,
i.e. there should be no solder mask between adjacent
terminal fingers.
Thermal Pad Via Design
Thermal data (θja) for the MLP18 is based on a 4 layer
PCB incorporating vias which act as the thermal path to
other layers. (Ref: Jedec Specification JESD 51-5). Based
on thermal performance, four-layer PCB’s with vias are
recommended to effectively remove heat from the device.
Vias should be 0.3mm diameter on a 1.2mm pitch, and
should be plugged to prevent voids being formed between
the exposed pad and PCB thermal pad due to solder
escaping by capillary action. Plugging can be accomplished
by “tenting” the via during the solder mask process. The
via solder mask diameter should be 100µm larger than
the via diameter.
Two layer boards have no vias, thus any heat sinking must
be accomplished in the same plane as the metal traces.
This will typically require an increase in the PC board area.
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Exposed Pad Stencil Design
It is good practice to minimize the presence of voids within
the exposed pad inter-connection. Total elimination is
difficult but the design of the exposed pad stencil is
important, a single slotted rectangular pattern is
recommended. (If large exposed pads are screened with
excessive solder, the device may “float”, thus causing a
gap between the MLP terminal and the PCB land
metalization.) The proposed stencil designs enables outgassing of the solder paste during reflow as well as
controlling the finished solder thickness.
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SC2615
POWER MANAGEMENT
Outline Drawing - MLP-18
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SC2615
POWER MANAGEMENT
Land Pattern - MLP-18
Contact Information
Semtech Corporation
Power Management Products Division
200 Flynn Road, Camarillo, CA 93012
Phone: (805)498-2111 FAX (805)498-3804
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