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APPLICATION NOTE
Discrete Power Supply Solution for Atmel SAMA5D4
Atmel | SMART SAMA5D4 Series
Scope
A wide variety of applications based on Atmel® | SMART SAMA5D4x embedded
MPUs (eMPUs) can be powered from a low-cost power supply solution based on
discrete components.
This application note provides developers with a recommended application
schematic and associated functional descriptions.
Reference Documents
Type
Title
Atmel Lit. No.
Datasheet
SAMA5D4 Datasheet
11238
SMART
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
Table of Contents
1.
Power Supply Overview of Atmel eMPU Systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1
1.2
1.3
1.4
1.5
1.6
2.
Reference Schematic and Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
2.1
2.2
3.
Atmel SAMA5D4x Power Rails . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Atmel SAMA5D4x VCCCORE Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
Atmel SAMA5D4x VDDBU Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Power Supply Topologies and Power Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Clock Circuits Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Power Supplies Monitoring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Basic Reference Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Wake-Up and Shutdown Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Variations from the Reference Schematic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
3.1
3.2
3.3
Applications Without Backup Battery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Input Power-Fail Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Discrete Components Selection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
2
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
1.
Power Supply Overview of Atmel eMPU Systems
1.1
Atmel SAMA5D4x Power Rails
Atmel SAMA5D4x eMPUs power rails and their respective operating ranges are listed in Table 1-1. An
approximate current consumption is provided for each rail in order to size the corresponding regulator. Accurate
numbers and descriptions are provided in the SAMA5D4 datasheet.
Depending on the application complexity, SAMA5D4x power input pins may be grouped into two (e.g., 3.3V +
1.8V), three (e.g., 3.3V + 1.8V + 1.2V) or more power planes. In secure applications, or any application that
requires writing into the internal fuse box, an additional 2.5V power rail is needed to supply the VDDFUSE input
pin.
The SAMA5D4x series also features a backup power domain to retain information during power-down periods by
means of a storage element (e.g., a battery or a super-capacitor). It is supplied by the VDDBU pin and must be fed
through a 2V regulator.
Table 1-1.
SAMA5D4x Series Power Supply Inputs
Power Rail
Circuit Supplied by the Power Rail
Range
Consumption
VDDCORE
Core Voltage Regulator
1.62–1.98V, 1.80V
0.35A
VDDIODDR
External Memory Interface I/O lines
1.70–1.90V, 1.80V
1.14–1.32V, 1.20V
0.05A
0.03A
VDDIOM
NAND and HSMC Interface I/O lines
1.65–1.95V, 1.80V
3.00–3.60V, 3.30V
0.03A
VDDIOP
Peripheral I/O lines
1.65–3.60V
0.03A
VDDUTMIC
USB Device and host UTMI+ core logic
and UTMI PLL
1.10–1.32V, 1.20V
0.02A
VDDUTMII
USB Device and host UTMI+ interface
3.00–3.60V, 3.30V
0.02A
VDDPLLA
PLLA
1.10–1.32V, 1.20V
0.02A
VDDOSC
Main oscillator
1.65–3.60V, 3.30V
0.001A
VDDANA
Analog-to-Digital Converter, and other analog
circuits
3.00–3.60V, 3.30V
–
VDDFUSE
Programmable Fuse Box
2.25–2.75V, 2.50V
0.05A
VDDBU
Backup domain
1.88–2.12V, 2.00V
0.0001A
In all modes other than Backup mode, each power supply input must be powered to operate the device. The only
exception is the VDDFUSE input which can be left unpowered if the fuse box is not used in Write mode.
1.2
Atmel SAMA5D4x VCCCORE Generation
Atmel SAMA5D4x devices embed a linear low dropout (LDO) voltage regulator to generate their core logic power
supply (VCCCORE). The input of this regulator is VDDCORE and its output is internally connected to some of the
VCCCORE pins. The remaining VCCCORE pins are fed from the VCCCORE plane of the printed circuit board
(PCB). This plane must contain at least one 10µF capacitor (max 20µF) to ensure the regulator stability. Additional
10nF to 100nF capacitors of X5R or X7R type must be connected to each VCCCORE pin for proper decoupling.
This LDO voltage regulator cannot be shut down. Therefore the VCCCORE pins cannot be fed by an external
voltage regulator at the risk of creating a short circuit between the internal regulator and the external one.
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
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1.3
Atmel SAMA5D4x VDDBU Generation
The SAMA5D4x series embeds a backup power domain which supplies a Real-Time Clock circuit, a backup
memory and others. This power domain is designed for ultra-low-power consumption (8µA typ.) and is therefore
suited to be supplied by a storage element such as a super-capacitor or a battery. The operating range of VDDBU
(2V±120mV) calls for the use of an external voltage regulator. Low-power LDO regulators in the S-1206 series
from Seiko Instruments and NCP4682 series from ON Semiconductor with a typical 1µA operating current meet
the criteria.
Figure 1-1.
VDDBU Generation
5.0V
(Main Power
Source)
3.0V
Backup
Battery
2.0V
LDO
(e.g :
BAV70L)
1μF
(e.g : S-1206 series
or NCP4682 series)
VDDBU
1μF
As described in the SAMA5D4x series datasheet, the VDDBU power supply must always be the first power source
applied to the system and the last one disconnected from the system. It is therefore good practice to monitor the
storage element discharge in order to shutdown the system before the VDDBU voltage goes out of its operating
range,
If the backup functionality of the SAMA5D4x device is not used in the application, VDDBU can be fed directly from
the main power source through a 2.0V regulator. In this case, a low-power regulator is not necessary. A generic
low-cost device (e.g. TLV431A or equivalent) can be chosen. In case of input power loss, small storage capacitors
(e.g., 1µF) help to extend the presence of the VDDBU voltage after a system shutdown as specified in the device
datasheet.
1.4
Power Supply Topologies and Power Distribution
1.4.1
2-channel Topology with 1.8V (DDR2 or LPDDR) Memories
When SAMA5D4x devices are equipped with 1.8V external memories (LPDDR or DDR2 type), the lowest cost
power supply is achieved by implementing a 2-rail topology (3.3V / 1.8V) as shown in Figure 1-2. While optimized
from a system cost perspective, this topology has the following limitations:

The fuse box cannot be accessed in Write mode because VDDFUSE = 0V.

The analog section of the device (VDDANA) is powered from the (noisy) digital 3.3V rail.
These limitations can be overcome by adding two regulators for VDDANA and VDDFUSE. In such case, these
regulators should be enabled and disabled along with the main 3.3V regulator.
4
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
Figure 1-2.
2-channel Power Supply Example on SAMA5D4x Series Equipped with a 1.8V External Memory
1.8V
VDDIODDR
VDDCORE
REG1
VCCCOREx
Core
Regulator
VDDUTMIC
VDDPLLA
VDDIOP
VDDIOM
VDDOSC
3.3V
REG2
VDDUTMII
VDDANA
100R
VDDFUSE
2.0V
LDO
3.0V
Coin Cell
Battery
1.4.2
VDDBU
SAMA5D4x
3-channel Topology with (1.2V / 1.8V) LPDDR2 memories
The 2-channel topology can be extended to support LPDDR2-type external memories. An additional 1.2V voltage
regulator is added to supply the LPDDR2 interface. See Figure 1-3.
Figure 1-3.
3-channel Power Supply Example on SAMA5D4x Series (LPDDR2 support)
1.2V
REG3
VDDIODDR
1.8V
VDDCORE
REG1
VCCCOREx
Core
Regulator
VDDUTMIC
VDDPLLA
VDDIOP
VDDIOM
3.3V
VDDOSC
VDDUTMII
VDDANA
REG2
100R
VDDFUSE
3.0V
Coin Cell
Battery
2.0V
LDO
VDDBU
SAMA5D4x
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
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1.5
Clock Circuits Power Supply
Atmel eMPUs have separate power supply inputs for their oscillators and PLL circuits. These analog circuits can
be decoupled from the digital (core and I/Os) activity of the device and thus generate less jittered clocks. Atmel
highly recommends feeding these power supply inputs with low-noise sources for applications where clock jitter is
important (e.g., high-speed USB). The simplest way to do this is to filter the digital rails with an LC network as
shown in Figure 1-4. Choosing a 20 kHz corner frequency is a good trade-off between component size/cost and
the necessary high-frequency attenuation for clock circuits. The inductors must be sized for low DC resistance and
good DC superimposition characteristics (TDK MLZ series and Taiyo Yuden CBM series are possible choices).
The serial resistor in the filter schematic must be adjusted to take the inductor DCR into account. Example of
inductors: Taiyo Yuden CBMF1608T100K (10 µH, 0.36 Ω, 115 mA, 0603) and TDK MLZ1608N100L (10 µH, 0.6 Ω,
60 mA, 0603).
Figure 1-4.
Recommended Filter on Clock Circuits Power Supply
2.2
10µH
VDDOSC
VDD_3V3
4.7µF 10nF
2.2
10µH
VDDPLLA
VCCCORE
4.7µF 10nF
1.6
Power Supplies Monitoring
Atmel MPU power rails are not internally monitored. In low-cost systems, when the input power can be removed
without advising the application, it is recommended to monitor the input voltage to detect the input power loss. In
this power-fail case, the application should start a power-off sequence. This is particularly relevant in SAMA5D4
systems equipped with LPDDR2 memories for which uncontrolled power-off conditions may lead to damage to the
memory IC.
6
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
2.
Reference Schematic and Description
2.1
Basic Reference Schematic
Basic Reference Schematic
4
C29
1μF
VDD
5
NC
2
EN
8
C14
10μF
U1 RT9018B-18GSP
VIN
VOUT
GND
GND(PAD)
3
GND
VDD_3V3
6
R56 1Meg
PGOOD
1
ADJ
7
R47
47k 1%
9
VIN
GND
R45 47k
C12
100nF
C15
4.7nF
EN1
C8
10μF
R46
15k 1%
PG33
R44 1MΩ
GND
GND
GND
EN2
1
NC
2
EN
5
GND
GND
GND(PAD)
C17 VDD_3V3
10μF
D1
U2 RT8010GQW
VIN
R48 100kΩ
C18
100nF
L3 2.2μH
LX
VDD_1V8
4
C9
22pF
FB
R38
100k 1%
C10
10μF
6
R39
49.9k 1%
7
3
GND
GND
GND
VDD_3V3
R54
100k
NMOS Qx : 2N7002
or BSS138
Diodes Dx : 1N4148
R58
6.04k
EN1
R59
59k
STARTB
R60
100k
SHDN
Q1
(From eMPU)
R57
10k
NRST_3V3
Q2
Q3
C21
1nF
GND
C22
1nF
Q4
PG33
Q5
NRST
(2V, To eMPU)
VDD_1V8
C20
10μF
4
EN3
VDD
5
NC
2
EN
8
C19 VDD_3V3
D2
1μF
U3 RT9018B-18GSP
VIN
VOUT
GND
GND(PAD)
3
GND
GND
VDD_1V8
VDD_1V2
6
R40 100k
PGOOD
1
ADJ
7
R41
23.7k 1%
9
Figure 2-1.
C23
10μF
R50
47k 1%
GND
GND
R43 100kΩ
C11
33nF
GND
Optional 1.2V generation
(LPDDR2 memory case)
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
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In this schematic, the power input VIN ranges from 3.5V to 5.5V. The lower limit (3.5V) is set by the need to
generate a 3.3V voltage (VDD_3V3) to feed some of the eMPU rails.
VIN supplies a linear low dropout regulator (U1) to make the VDD_3V3 voltage and a DCDC buck regulator (U2) to
make the VDD_1V8 voltage. In designs embedding an LPDDR2 memory, an optional VDD_1V2 supply channel
can be built from the VDD_1V8 rail with a low input voltage low dropout regulator (U3).
Low-cost discretes are used to control the regulators’ enable pins (EN) and the NRST signal of the SAMA5D4
device. As demonstrated in the following, this schematic ensures proper supply sequencing and reset assertion
during power-up and power-down phases.
This power supply is designed to be controlled by the eMPU Shutdown Controller (SHDWC) and its SHDN pin.
Refer to the section “Shutdown Controller (SHDWC)” in the SAMA5D4 datasheet for a complete description. In
summary, SHDN is high when the eMPU is running, and SHDN is low when the eMPU goes to Backup mode or to
OFF mode. The SHDN pin defaults to ‘1’ (VDDBU level) when VDDBU is first applied. Figure 2-2 shows a typical
application timing diagram and in particular the use of the Shutdown Controller.
Figure 2-2.
Typical Application Timing Diagram
VIN
VDDBU
(2.0V Regulated)
App. Status
Software Shutdown routine
with shutdown command
OFF
Supply Start.
Processor Reset
Application is running...
Application is in Backup Mode.
RTC is running...
Supply Start.
Proc. Reset
Backup mode exit
upon wake-up event
(e.g., RTC alarm)
SHDN
(VDDBU level)
Wake-Up event
(e.g WKUP0)
VDD_3V3
VDD_1V8
VDD_1V2
(if needed)
nRST
~40 ms
8
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
~40 ms
Application
is running...
2.2
Wake-Up and Shutdown Description
2.2.1
Wake-Up Description
Figure 2-3 shows the typical wake-up waveforms of the basic reference schematic power supply. In the left-hand
image, upon a wake-up event (not shown here), the processor pulls the SHDN pin high (VDDBU level 2.0V) and
exits Backup mode. SHDN is applied through Q1 and Q2 to the enable pin of U1. The delay between SHDN and
the start of regulator U1 is tuned with the (R44 + R45) / C15 network (here about 2ms, shown in the right-hand
image). U1 starts regulating the VDD_3V3 output to 3.3V which enables the U2 regulator through the R48 / C18
delay network (here about 5ms). When applicable, regulator U3 is started by VDD_1V8 presence through the R43
/ C11 delay network (here about 3ms). When VDD_1V8 rises, SAMA5D4’s internal VCCCORE LDO regulator
starts to regulate VCCCORE to 1.2V (See right-hand figure).
During this startup phase, the processor is held in reset (NRST low) with a delayed version of the PGOOD (powergood) output of U1. The delay network is made by (R56 / C12), here about 35ms. Q4 / Q5 / R56 / C13 shape the
slowly rising PG33 signal. The resistor ladder R58 / R59 / R60 makes a 2V level reset signal (NRST) for the
SAMA5D4 device and a generic 3.3V reset signal (NRST_3V3) for other components on the board.
Figure 2-3.
Wake-up Waveforms
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
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2.2.2
Shutdown Description
Figure 2-4 shows the typical shutdown waveforms of the reference schematic power supply. In the left-hand
image, upon a shutdown request in the Shutdown Control register (SHDW_CR), the processor pulls the SHDN pin
low and enters Backup mode. NRST is almost immediately pulled low through Q1, Q2 and Q3. The delay between
the SHDN falling edge and the NRST signal assertion is less than 10µs and depends on the R54-CSTARTB delay.
C STARTB is a sum of parasitic capacitances at node STARTB (Q1’s drain capacitance, Q2 and Q3’s gates
capacitances). After the R45 / C15 delay (about 100µs as depicted in the right-hand image), the enable pin of U1
falls. U1 stops and discharges its output capacitor through its internal discharge resistor. When VDD_3V3 falls, it
discharges C18 through D1 and C11 and D2. The enable pins of U2 and U3 are pulled low, thus stopping these
regulators.
Figure 2-4.
10
Shutdown Waveforms
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
3.
Variations from the Reference Schematic
3.1
Applications Without Backup Battery
To start the power supply described in Figure 2-1, the SHDN output of the SAMA5D4 must be set to a high level.
The SHDN pin, which is part of the VDDBU power domain of the Atmel device, defaults to a high level when
VDDBU is applied for the first time, thus ensuring a safe first start-up of the application. If VDDBU is not built from
an always-on source (like a battery), it is convenient to regulate VDDBU voltage from the input power source (VIN)
rather than from one output of the power supply. This way, the SHDN pin and, more generally, the Shutdown
Controller are properly supplied before the power supply starts and after the shutdown command.
Figure 3-1.
Applications Without Backup Battery
Atmel SAMA5D4x
REG 2
VIN
VDD_1V8
VDDIODDR
VDDCORE
VCCCOREx
Core
Regulator
VDDUTMIC
VDDPLLA
REG 1
VDDIOP
VDDIOM
VDDOSC
VDDUTMII
VDDANA
VDD_3V3
100R
VDDFUSE
SHDN
SHDN
NRST
NRST
2.0V
LDO
VDDBU
(e.g. TLV431A)
3.2
Input Power-Fail Detection
It is possible to add an input power-fail detection circuit to the basic reference schematic depicted in Figure 2-1.
The principle, described in Figure 3-2, is to monitor the input voltage VIN and to warn the processor with an
interrupt in case of power loss. The Fast Interrupt (FIQ) input or any I/O configured as an interrupt input may be
used. Upon this interrupt request, a software power- off sequence is started during which some data storage
and/or service shutdown may be performed depending on the remaining ”ON” time. This power-off sequence then
ends by setting the bit SHDW in SHDW_CR. The SHDN pin falls down to 0 which turns off the power supply, as
described in Section 2.2.2 “Shutdown Description” on page 10.
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
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Figure 3-2.
Power Loss Management Principle
Atmel SAMA5D4x
VDD_1V8
REG 2
VIN
VDDIODDR
VDDCORE
VCCCOREx
Core
Regulator
VDDUTMIC
VDDPLLA
VDDIOP
VDDIOM
VDDOSC
VDDUTMII
VDDANA
VDD_3V3
REG 1
100R
VDDFUSE
SHDN
SHDN
NRST
NRST
Input
Power Fail
Detector
FIQ or
PIO in IRQ mode
VIN or
Battery
2.0V
LDO
VDDBU
To monitor the input voltage VIN, several solutions are possible depending on available resources at system level.
(e.g., a system with a voltage reference on-board only requires an additional voltage comparator). Figure 3-3
shows one possible implementation using an integrated voltage monitor circuit.
Figure 3-3.
Input Power-Fail Detection Examples
VDD_3V3
VIN
R2
10k
U4 NCP302
3
VCC
RSTB
2
FIQ
or PIO (IRQ mode)
GND
1
GND
12
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
Atmel-44023A-ATARM-Discrete Power Supply Solution for Atmel SAMA5D4-ApplicationNote_04-Feb-15
3.3
Discrete Components Selection
The discrete components listed in this application note are given as implementation examples. They are not strong
recommendations. The reader may adapt the presented schematics to his specific needs and still keep the basic
principles described in the previous sections. As the focus of this application note is the solution cost, only low-cost
components are selected. This may lead to “over-sized” components compared to the real application need
because they give the best price in this particular case. While cost and ease of procurement are the primary
criteria for component selection, other criteria have to be considered to select other types of components:

Regulators: Devices should feature an enable input and a power-good output as they ease the design of the
power sequencing and reset generation circuits.

NMOS transistors: Low threshold voltage (< 2V) devices are best to ensure safe commutation in all cases
(VDDBU is regulated to 2V).

Diodes: Any general-purpose, small signal device with a low reverse current specification (<20nA at 20V and
25°C) is suitable.
Discrete Power Supply Solution for Atmel SAMA5D4 [APPLICATION NOTE]
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13
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authorized, or warranted for use as components in applications intended to support or sustain life.
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the failure of such products would reasonably be expected to result in significant personal injury or death (“Safety-Critical Applications”) without an Atmel officer's specific written
consent. Safety-Critical Applications include, without limitation, life support devices and systems, equipment or systems for the operation of nuclear facilities and weapons systems.
Atmel products are not designed nor intended for use in military or aerospace applications or environments unless specifically designated by Atmel as military-grade. Atmel products are
not designed nor intended for use in automotive applications unless specifically designated by Atmel as automotive-grade.