CUI NDM2Z-12HT-AB Auto compensated, digital dc-dc pol converter Datasheet

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date 11/07/2014
page
1 of 14
MODEL: NDM2Z-12H │ DESCRIPTION: AUTO COMPENSATED, DIGITAL DC-DC POL CONVERTER
GENERAL CHARACTERISTICS
•
•
•
•
•
•
•
•
•
•
4.5~14 V input range
0.6~5.0 V programmable output
voltage tracking
voltage margining
Snapshot™ parametric capture
voltage/current/temperature monitoring
synchronization and phase spreading
remote differential voltage sense
programmable soft start and soft stop
fault management
MODEL
FEATURES
• compact package
horizontal:
21.0 x 12.7 x 7.2 mm
(0.827 x 0.500 x 0.284 in)
• 12 A output
• high efficiency
• auto compensation
• SMBus interface
• PMBus™ Compatible
• Ericsson footprint compatible
input voltage
NDM2Z-12H
output voltage
output current
output wattage
(Vdc)
(Vdc)
max
(A)
max
(W)
4.5~14
0.6~5.0
12
60
PART NUMBER KEY
NDM2Z-12H X - X X - XXX
Base Number
Pin Style:
S = surface-mount
T = through-hole
Firmware Configuration:
000~ZZZ
Pin Configuration:
A = standard
configuration
Package Option:
A = loose parts
B = tape and reel
C = tray
Example part number: NDM2Z-12HT-AA-002
horizontal module
through-hole pins
standard pin configuration
loose parts package option
firmware configuration 002
CONTENTS
Absolute Maximum Ratings.................................2
Recommended Operating Conditions....................2
Pin Descriptions................................................3
Typical Characteristics.......................................4~5
Mechanical Drawing..............................................6
Operating Information.....................................7~13
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date 11/07/2014 │ page 2 of 14
ABSOLUTE MAXIMUM RATINGS
parameter
conditions/description
min
Vin
input voltage
digital pin voltage
CTRL, DDC, SA0, SALRT, SDA, SCL, SYNC, VSET,
PG
analog pin voltage
max
units
15
V
-0.3
6.5
V
+S, -S, VTRK
-0.3
6.5
V
ground voltage differential
(GND - PREF)
-0.3
0.3
V
operating temperature
TP1
-40
120
°C
-55
125
°C
storage temperature
typ
RECOMMENDED OPERATING CONDITIONS
-30°C < TP1 < +95°C, 4.5 V < Vin < 14 V, typical measurements made at Vin = 12 V, Vout = 1.0 V, Iout = Imax, TP1 = 25°C,
=Cin = 470 μF/10 mΩ, Cout = 470 μF/8 mΩ
INPUT / OUTPUT
parameter
conditions/description
min
Vin
input supply voltage
Iout
output current
Vout
adjustable via resistor or PMBus™ commands
0.6
5.0
V
Vout margin
adjustable via PMBus commands
0
110
%
voltage accuracy
over line, load and temperature
measured at +S and -S
-1
1
%
line regulation
4.5
Vout
Vout
Vout
Vout
load regulation
0 A ≤ Iout ≤ Imax
Vout = 0.6 V
Vout = 1.0 V
Vout = 1.8 V
Vout = 3.3 V
voltage set-point resolution
when Vout set via PMBus commands
voltage ripple and noise
Vout
Vout
Vout
Vout
ramp-up time
adjustable via PMBus
0
200
ms
on time delay
adjustable via PMBus
5
500,000
ms
load transient voltage deviation
Iout: 25%
Vout = 0.6
Vout = 1.0
Vout = 1.8
Vout = 3.3
V
V
V
V
load transient recovery time1
Iout: 25%
Vout = 0.6
Vout = 1.0
Vout = 1.8
Vout = 3.3
V
V
V
V
Notes:
max
units
4.5
14
V
0
12
A
V ≤ Vin ≤ 14 V
= 0.6 V
= 1.0 V
= 1.8 V
= 3.3 V
=
=
=
=
0.6
1.0
1.8
3.3
typ
2.4
2.2
1.7
2.8
mV
0.4
0.6
0.6
2.6
-0.025
V
V
V
V
mV
0.025
12
18
21
21
75%
75%
25% of Imax, dI/dt=2 A/μs
25% of Imax, dI/dt=2 A/μs
1. settling to within 3% of Vout
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56
77
102
160
TBD
20
0
0
% FS
mVp-p
mV
µs
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date 11/07/2014 │ page 3 of 14
POWER / EFFICIENCY
parameter
conditions/description
min
output power
Vout = 5.0 V + 10% margin
0
max
units
66
W
Iout = 50% of max
Vout
Vout
Vout
Vout
=
=
=
=
0.6
1.0
1.8
3.3
V
V
V
V
85.3
89.8
92.7
94.2
%
Iout = max
Vout
Vout
Vout
Vout
=
=
=
=
0.6
1.0
1.8
3.3
V
V
V
V
81.1
86.6
90.9
93.3
%
0.45
0.58
0.94
1.78
0.13
W
320
kHz
efficiency
Vout = 0.6 V
Vout = 1.0 V
Vout = 1.8 V
Vout = 3.3 V
CTRL deasserted
idle power
typ
switching frequency
FAULT PROTECTION
parameter
conditions/description
min
output over voltage protection
output over current protection
input under voltage protection
adjustable via PMBus commands
input over voltage protection
adjustable via PMBus commands
over temperature protection
(OTP) measured on the module
thermal protection hysteresis
difference between temperature fault and warning
typ
max
units
(OVP) adjustable via PMBus commands
5.6
V
(OCP) adjustable via PMBus commands
TBD
A
4.5
14
V
125
°C
15
°C
POWER CONNECTIONS
symbol
pin
IO type
VIN
1A
Power
Input voltage
GND
2A
Ground
Power ground
VOUT
3A
Power
Output voltage
description
COMMUNICATION CONNECTIONS
symbol
pin
IO type
description
VTRK/PG
4A
Analog/Digital
Voltage tracking input or power good output
PREF
4B
Ground
Pin-strap ground
+S
5A
Analog
Output voltage positive sense input
-S
5B
Analog
Output voltage negative sense input
SA0
6A
Digital
SMBus address pinstrap
DDC
6B
Digital
Digital-DC Communications bus (equivalent to Ericsson Power GCB)
SCL
7A
Digital
SBMBus clock
SDA
7B
Digital
SMBus data
VSET
8A
Digital
Output voltage pin-strap
SYNC
8B
Digital
Synchronization I/O
SALRT
9A
Digital
SMBus alert
CTRL
9B
Digital
Remote control or enable pin
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V
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date 11/07/2014 │ page 4 of 14
LOGIC INPUT/OUTPUT CHARACTERISTICS
parameter
conditions/description
min
input high voltage (VIH)
CTRL, DDC, SA0, SCL, SDA, SYNC, VSET
input low voltage (VIL)
CTRL, DDC, SA0, SCL, SDA, SYNC, VSET
output high voltage (VOH)
DDC, SALRT, SDA, SYNC, PG
output low voltage (VOL)
DDC, SALRT, SDA, SYNC, PG
typ
max
2
units
V
0.8
2.25
V
V
0.4
V
max
units
15,000
µF
OUTPUT DECOUPLING CAPACITOR RECOMMENDATION
parameter
conditions/description
min
COUT
total output capacitance located on host board
300
typ
DDC CONFIGURATION REQUIREMENTS
A pull-up resistor is required on the DDC in order to guarantee the rise time as follows:
Rise TimeDDC = RDDC * CDDC < 1 µs
RDDC is the DDC pull-up resistor and CDDC is the DDC capacitive loading. The pull-up resistor should be tied to an external 3.3V or 5V
supply. The designer needs to ensure that the resistor pull-up voltage is present during module power-up. Each module connected to
the DDC presents ~10 pF, each inch of FR4 PCB trace introduces ~2 pF of capacitive loading.
SMBUS CONFIGURATION REQUIREMENTS
The complete specifications for the SMBus can be found on the following web pages: www.pmbus.info , smbus.org
TYPICAL CHARACTERISTICS
Conditions (applies to all graphs unless stated otherwise):
TP1 = 25°C, Vin = 12 V, Cin = 470 μF/10 mΩ, Cout = 470 μF/8 mΩ, Iout = Imax
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CUI Inc │ MODEL: NDM2Z-12H │ DESCRIPTION: AUTO COMPENSATED, DIGITAL DC-DC POL CONVERTER
TYPICAL CHARACTERISTICS (CONTINUED)
Conditions (applies to all graphs unless stated otherwise):
Start-up
Shut-down
(Vout = 1.0 V)
(Vout = 1.0 V)
Output Load Transient Response
(Vout = 1.0 V, Iout = 3.0
TP1 = 25°C, Vin = 12 V, Cin = 470 μF/10 mΩ, Cout = 470 μF/8 mΩ, Iout = Imax
9.0
3.0 A, 2 A/μs)
Output Ripple and Noise
(Vout = 1.0 V)
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date 11/07/2014 │ page 5 of 14
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MECHANICAL DRAWING
THROUGH-HOLE
units: mm [inches]
tolerance unless specified:
X.X ±0.50 [0.02]
X.XX ±0.25 [0.01]
(not applied on footprint or typical values)
B
12.700 0.500
21.006 0.827
TOP VIEW
PIN
NUMBER
7.225 0.284
FRONT VIEW
2.000 0.079
2.000 0.079
2.000 0.079
1A
6.200 0.244
13.700 0.539
2A
9.700 0.382
3A
1.016 0.040
(3 PLCS)
2.000 0.079
9A
9B
8A
8B
7A
7B
6A
6B
5A
5B
4A
4B
1.850 0.073
2.000 0.079
(5 PLCS)
0.889 0.035
(12 PLCS)
16.000 0.630
22.000 0.866
PCB LAYOUT
TOP VIEW
Recommended keep out area for user components
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PIN
NAME
1A
VIN
2A
GND
3A
VOUT
4A
VTRK/PG
4B
PREF
5A
+S
5B
-S
6A
SA0
6B
DDC
7A
SCL
7B
SDA
8A
VSET
8B
SYNC
9A
SALRT
9B
CTRL
MATERIAL
PLATING
Au 0.25 μm
over Ni 2.5
μm
Copper Alloy
Au 0.76 μm
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date 11/07/2014 │ page 7 of 14
MECHANICAL DRAWING (CONTINUED)
SURFACE MOUNT
units: mm [inches]
tolerance unless specified:
X.X ±0.50 [0.02]
X.XX ±0.25 [0.01]
(not applied on footprint or typical values)
A
12.700 0.500
21.006 0.827
TOP VIEW
PIN
NUMBER
7.225 0.284
0.90 0.035
(12 PLCS)
1.60 0.063
(3 PLCS)
FRONT VIEW
2.000 0.079
2.000 0.079
18.000 0.709
2.000 0.079
1A
6.200 0.244
13.700 0.539
2A
9.700 0.382
3A
2.100 0.083
(3 PLCS)
0.150 0.006
PIN
NAME
1A
VIN
2A
GND
3A
VOUT
4A
VTRK/PG
4B
PREF
5A
+S
5B
-S
6A
SA0
6B
DDC
7A
SCL
9A
9B
7B
SDA
8A
8B
8A
VSET
7A
7B
8B
SYNC
9A
SALRT
9B
CTRL
6A
6B
5A
5B
4A
4B
2.000 0.079
(5 PLCS)
1.300 0.051
(12 PLCS)
22.000 0.866
PCB LAYOUT
TOP VIEW
Recommended keep out area for user components
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MATERIAL
PLATING
Au 0.1 μm
over Ni 1~3
μm
Copper Alloy
Au 0.1 μm
over Ni 2 μm
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CUI Inc │ MODEL: NDM2Z-12H │ DESCRIPTION: AUTO COMPENSATED, DIGITAL DC-DC POL CONVERTER
OPERATING INFORMATION
POWER CONVERSION AND MANAGEMENT
The NDM2Z-12 modules are available in different
configurations; not all pins and functions are supported by
each configuration. This document describes all pins and
functions.
The Novum Z Products PMBus Commands application note
defines the available PMBus™ commands.
REQUIRED CONFIGURATIONS
NDM2Z-12 Module Pins
Each NDM2Z-12 module should have a resistor placed
between VSET and PREF to set the output voltage of the
module. The maximum output voltage which can be
configured by PMBus commands can never exceed 110% of
the voltage set by the VSET pin. The SMBus address of each
module is set by either pin-strap configuration or resistor value associated with the SA0 pin. More information
regarding setting the SMBus address for a module can be
found in the section titled “SMBus”.
PCB Layout
Good performance of any point of load voltage regulator
module can only be achieved with careful PCB layout
considerations. Ground planes or very wide traces should
be used for power and ground routing. Input capacitors
should be placed close to the input voltage pins of the
module and output capacitors should be placed close to the
load. The module should also be placed as close as possible
to the load.
INPUT AND OUTPUT CAPACITORS
Input Capacitors
Input capacitors are recommended to be used with the
NDM2Z-12 module in order to minimize input voltage ripple.
A 330 μF POSCAP or electrolytic and 3x 22 μF ceramic
capacitors should be placed as close as possible to the input
pins of the module. Additional input capacitors may be
used if less input voltage ripple is desired.
Output Capacitors
Output capacitors are recommended to be used with the
NDM2Z-12 module in order to improve transient response
and minimize output voltage ripple. A 330 μF POSCAP or
electrolytic and 3x 22 μF ceramic capacitors should be
placed as close as possible to the load. Additional output
capacitors may be used to further improve the output
voltage characteristics.
date 11/07/2014 │ page 8 of 14
Power Conversion Overview
The NDM2Z-12 module has several features to enable high
power conversion efficiency. Non-linear loop response (NLR)
improves the response time and reduces the output
deviation as a result of load transients. The incorporation
of DFM enhances the performance of CUI modules over that
available from conventional analog POL offerings.
Power Management Overview
The NDM2Z-12 module incorporates a wide range of power
management features. All power management functions
can be configured via the SMBus interface. The NDM2Z-12
can monitor and report many characteristics of the module
including input voltage, output voltage, output current and
internal temperature. Additionally, the NDM2Z-12 includes
circuit protection features that protect the module and load
from damage due to system faults. Monitoring parameters
can also be configured to provide alerts for specific
conditions. The ability of CUI modules to digitally control,
configure and monitor OS features provides significant
benefits over traditional analog POL products.
CONFIGURING THE MODULE
Pin Settings
Pin SA0 is used to set the SMBus address of the NDM2Z-12
module. Details of this feature are discussed in the section
titled “SMBus”. Pin SYNC is used to synchronize the switching clock of the module to an external clock source. More
information regarding synchronization can be found in the
section titled “SWITCHING FREQUENCY AND SYNCHRONIZATION”.
Pin VSET is used to configure the output voltage of the
module. The voltage established by the VSET pin limits the
maximum output voltage that can be configured by SMBus
commands.
The SA0, SYNC and VSET pin configurations are read by
the module when power is applied or whenever a SMBus
RESTORE command is issued.
The CTRL pin is active high and can be used to enable the
module. Internal connections on the module will drive the
CTRL pin high if it is left floating.
Pins +S and -S are used for remote voltage sensing of the
output voltage.
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date 11/07/2014 │ page 9 of 14
Unused Pins
Table 1 describes the required or allowed connections for unused pins on the NDM2Z-12 module.
Table 1: Unused Pins
VSET
Tie to PREF with 133 kΩ resistor, see VOUT_COMMAND PMBus command
VTRK/PG, SA0, SYNC, CTRL, +S, -S
Float
DDC, SCL, SDA, SALRT
Pulled high with resistor, see "RECOMMENDED OPERATIN CONDITIONS"
Configuration of Parameters Using the SMBus
The NDM2Z-12 module is supplied with default settings. All module settings (except for module SMBus address,
configured by pin SA0) can be re-configured via the SMBus interface. The output voltage can not be set to greater than
110% of the voltage set by the VSET pin.
START-UP PROCEDURE
Start-up Sequence
The NDM2Z-12 module follows an internal start-up procedure after power is applied to pin VIN. Table 2 describes the
start-up sequence. If the module is to be synchronized to an external clock source, the clock frequency must be stable
prior to asserting CTRL (or applying input voltage to the module if CTRL is not used). Once this process is completed, the
module is ready to accept assertion of CTRL and commands via the SMBus interface.
Table 2: NDM2Z-12 Start-up sequence
STEP
STEP NAME
DESCRIPTION
TIME DURATION
1
Power applied or
RESTORE_FACTORY
Input voltage is applied to NDM2Z-12 module pin VIN or RESTORE_FACTORY
PMBus command issued
Depends on input
supply ramp time
2
Factory configuration
settings
Module loads factory configuration settings. This step is also performed after
using PMBus commands to restore the factory configuration file.
3
SA0, SYNC and VSET
pin settings
Module loads values configured by the SA0, SYNC and VSET pins.
4
Default configuration
settings
Module loads default configuration settings. This data over-rides pin setting
data, except for maximum limit for VOUT_COMMAND. This step also performed
after using PMBus commands to restore the default configuration file.
5
User configuration
settings
Module loads user configuration settings. This data over-rides pin setting and
default configuration data, except for maximum limit for VOUT_COMMAND. This
step also performed after using PMBus commands to restore the user
configuration file.
6
Module ready
The module is ready to accept a CTRL signal.
---
7
Pre-ramp delay
The module requires approximately 5 ms following a CTRL signal and prior to
ramping its output. Additional pre-ramp delay may be configured using PMBus
commands.
Approximately
5 ms
Soft-start Delay Ramp Times
Once CTRL is asserted the NDM2Z-12 module requires a
pre-ramp delay time before the output voltage may be
allowed to start the ramp-up process. After the delay period
has expired, the output will begin to ramp towards the
target voltage according to the pre-configured soft-start
ramp time that has been set. It is recommended to set the
soft-start ramp time to a value greater than 500 μs in order
to prevent fault conditions due to excessive inrush current.
Soft start delay and ramp times may be set using PMBus
commands.
Output Pre-Bias
An output pre-bias condition exists when a non-zero
Approximately 10
ms (module will
ignore a CTRL
signal and PMBus
commands during
this period)
voltage is present on the NDM2Z-12 module output before
the module output voltage is enabled. If a pre-bias voltage
exists, the output voltage of the module is set to match the
existing pre-bias voltage. The output voltage is then ramped
to the final regulation value in the specified ramp time.
The pre-bias voltage can be higher or lower than the final
output voltage. Higher pre-bias output voltages will cause
energy to be pumped into the input voltage rail powering
the module. This condition could cause the module to report
an error condition if the input voltage exceeds the input
over voltage lock out threshold. The module will report an
error condition if the pre-bias output voltage exceeds the
output over voltage protection threshold.
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Power Good
The PG pin on the NDM2Z-12 module will assert if the
output of the module is within tolerance of the target
voltage and no fault conditions exist. A PG delay period
is defined as the time from when all conditions within the
module for asserting PG are met to when PG is actually
asserted. By default, PG delay is set equal to the soft-start
ramp time setting. The tolerance, polarity and delay of PG
may be configured via PMBus commands.
Soft-stop Delay and Ramp Times
After CTRL is de-asserted the NDM2Z-12 module utilizes
a pre-ramp delay time before the output starts the rampdown process. After the delay period has expired, the
output will begin to ramp towards ground according to the
pre-configured soft-stop ramp time that has been set. It is
recommended to set the soft-start ramp down to a value
greater than 500 μs in order to prevent voltage spikes in
the module input supply rail due the energy stored in the
output capacitors. There will be a delay after the output
voltage has reached ground potential and then the output of
the module will be set to high impedance. Once the output
of the module is high impedance the output voltage may
float to a non-zero value if another source or leakage path
is connected to the output. The soft-stop delay and ramp
times may be configured via PMBus commands.
PMBus commands can be used to set the output of the
NDM2Z-12 module to high impedance as soon as the output
voltage drops below a selectable threshold.
OUTPUT VOLTAGE SETTING
Pin-Strap and Resistor Setting Methods
Using the pin-strap method, the voltage on the VOUT pin
of the NDM2Z-12 module can be set to one of three default
voltages as shown in Table 3. Table 4 lists the available
output voltage settings with a resistor connected between
VSET and PREF.
Table 3: Pin-strap VOUT voltage settings
VSET
VOUT (V)
LOW (< 0.8 V)
0.6
OPEN (N/C)
1.2
HIGH (> 2.0 V)
2.5
date 11/07/2014 │ page 10 of 14
Table 4: Resistor VOUT voltage settings
RESISTOR (kΩ)
VOUT (V)
RESISTOR (kΩ)
VOUT (V)
10.0
0.60
46.4
1.50
11.0
0.65
51.1
1.60
12.1
0.70
56.2
1.70
13.3
0.75
61.9
1.80
14.7
0.80
68.1
1.90
16.2
0.85
75.0
2.00
17.8
0.90
82.5
2.10
19.6
0.95
90.9
2.20
21.5
1.00
100.0
2.30
23.7
1.05
110.0
2.50
26.1
1.10
121.0
3.00
28.7
1.15
133.0
3.30
31.6
1.20
147.0
4.00
34.8
1.25
162.0
5.00
38.3
1.30
178.0
5.50
42.2
1.40
SMBus Setting Method
The voltage present at the VOUT pin of the NDM2Z-12
module can be reconfigured using PMBus commands. A
voltage level reconfigured by a PMBus command overrides the voltage set by the VSET pin, but cannot be set to
greater than 110% of the voltage set by the VSET pin.
Voltage Tracking
The NDM2Z-12 module includes a feature that allows the
output ramp voltage to track the ramp of a reference
voltage which is applied to the VTRK/PG pin. The voltage
ramp tracking capability can be configured so that member
modules track at either 50% or 100% of the reference
voltage ramp rate. In addition, a member module can be
configured so that the termination voltage either tracks
or ignores perturbations on the reference voltage once it
has stabilized. Tracking at 50% and tracking final voltage
perturbations is intended for DDR memory applications. All
other applications which required voltage tracking should
use 100% tracking and ignore final voltage perturbations.
The reference voltage for tracking must have a target voltage which is equal to or greater than the target voltage of
the member modules. The turn-on delay of the reference
voltage must be at least 10 ms greater than that set for the
member modules. In voltage tracking mode, the turn-off
delay of the member modules establishes the time duration
which the member modules will track the reference voltage
after CTRL is de-asserted. The turn-off delay of the member
modules must be at least 5 ms greater than the sum of the
turn-off delay and fall time of the reference voltage.
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Current sharing modules which are also configured to track
a voltage must have all of the VTRK/PG pins tied together.
All of the CTRL pins of the member modules must also be
connected together and driven by a common source. The
rise and fall times of the member modules should be set
between 5 ms and 10 ms to ensure current sharing while
ramping. PMBus commands can be used to configure the
voltage tracking features.
Voltage Margining
The NDM2Z-12 module offers a means to vary the output
voltage higher or lower relative to the nominal voltage
setting. The rate of change of the output voltage during
voltage margining is also configurable. The margin feature
can be reconfigured through PMBus commands.
SWITCHING FREQUENCY AND SYNCHRONIZATION
Switching Frequency
The switching frequency of the NDM2Z-12 module can
be reconfigured by PMBus commands or controlled by an
external clock source connected to the SYNC pin. If the
module is operated at a switching frequency of other than
the factory default setting, the compensation may need to
be adjusted and the ripple, noise, transient response and
efficiency may be affected.
SYNC Auto Detect
The NDM2Z-12 module will automatically check for a clock
signal on the SYNC pin after CTRL is asserted (or applying
input voltage to the module if CTRL is not used). If a clock
signal is present, the module will synchronize to the rising
edge of the external clock. The external clock signal must
be stable and conform to the “RECOMMENDED OPERATING
CONDITIONS” parameters when CTRL is asserted (or
applying input voltage to the module if CTRL is not used).
In the event of a loss of the external clock signal, the
output voltage of the module may show transient overshoot
or undershoot and the module will automatically configure
to switch at a frequency close to the previous incoming
frequency. If no incoming clock signal is present when CTRL
is asserted (or applying input voltage to the module if CTRL
is not used), the module will switch at the frequency set by
the configuration file.
date 11/07/2014 │ page 11 of 14
loop every time the output voltage ramps to the regulated
level. PMBus commands can be used to configure when the
module re-compensates the loop.
The user also has the option to manually configure the loop
compensation.
Non-Linear Response (NLR) Settings
The NDM2Z-12 module incorporates a non-linear response
(NLR) loop that decreases the response time and the output
voltage deviation in the event of a sudden output load
current step. This implementation results in a higher
equivalent loop bandwidth than what would be possible
using a traditional linear loop. PMBus commands can be
used to configure the NLR response of the module.
Adaptive Diode Emulation
Please contact CUI technical support regarding the
implementation of adaptive diode emulation.
Adaptive Frequency Control
The NDM2Z-12 module includes adaptive frequency control
to improve conversion efficiency. Adaptive frequency control
is not available for current sharing groups and is not
allowed when the module is placed in auto-detect mode
and a clock source is present on the SYNC pin.
Adaptive frequency control is only available while the
module is operating within adaptive diode emulation mode.
Adaptive frequency control can be enabled and disabled
with PMBus commands.
MULTI-MODULE CONFIGURATION
Output Sequencing
Multiple device sequencing of NDM2Z-12 modules may
be achieved by issuing PMBus commands to assign the
preceding device in the sequencing chain as well as the
device that will follow in the sequencing chain. The CTRL
pins of all devices in a sequencing group must be tied
together and driven high to initiate a sequenced turn-on of
the group. CTRL must be driven low to initiate a sequenced
turnoff of the group.
CONTROL LOOP
Adaptive Loop Compensation
The NDM2Z-12 module employs automatic adaptive loop
compensation to increase the performance and stability of
the module over a wide range of conditions. The default
setting configures the module to re-compensate the control
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CUI Inc │ MODEL: NDM2Z-12H │ DESCRIPTION: AUTO COMPENSATED, DIGITAL DC-DC POL CONVERTER
Fault Spreading
NDM2Z-12 modules can be configured to broadcast a fault
event over the GCB (Group Communication Bus) to the
other modules in the group. When a nondestructive fault
occurs and the module is configured to shut down on a
fault, the module will shut down and broadcast the fault
event over the GCB. The other modules on the GCB will
shut down together if configured to do so, and will attempt
to re-start in their prescribed order if configured to do so.
PMBus commands can be used to configure the
transmission and reception of faults.
Phase Spreading
When multiple NDM2Z-12 modules share a common DC
input supply, it may be desirable to adjust the clock phase
offset of each module. In order to enable phase spreading,
all modules must be synchronized to the same switching
clock. For modules driven by a common synchronizing clock
the phase offset of each module is controlled by the module
addresses; phase offset = device address x 45°.
For example:
• A module address of 0x00 or 0x20 would configure 0° of
phase offset
• A module address of 0x01 or 0x21 would configure 45° of
phase offset
• A module address of 0x02 or 0x22 would configure 90° of
phase offset
The phase offset of each module may also be set via the
PMBus.
POWER FAULT MANAGEMENT
Input Under and Over Voltage Lockout
Input under voltage lockout (UVLO) and input over voltage
lockout (OVLO) indicate faults for the NDM2Z-12 module
when the input voltage falls outside of preset thresholds.
The default response due to an input voltage fault is
an immediate shutdown of the module. The module will
continuously check for the presence of the fault condition.
Once the fault condition is no longer present, the module
will be re-enabled. PMBus commands can be used to
configure the thresholds and response of the module to the
fault condition.
Output Under and Over Voltage Protection
The NDM2Z-12 module employs an output voltage
protection circuit that can be used to protect load circuitry
from being subjected to voltages outside of prescribed
limits. A hardware comparator is used to compare the
voltage seen at the +S pin to voltage thresholds. If the +S
pin voltage is outside of these thresholds the PG pin will
de-assert and the module will indicate a fault condition.
date 11/07/2014 │ page 12 of 14
The default response to an output voltage fault is to
immediately shut down. The module will continuously check
for the presence of the fault condition, when the fault
condition no longer exists the module will be re-enabled.
PMBus commands can be used to set the voltage
thresholds and configure the response of the module to the
fault condition. When operating from an external clock the
only allowed response to an output voltage fault is an
immediate shutdown.
Output Over Current Protection
Output over current protection will protect the NDM2Z-12
module and load from damage if an overload condition is
imposed on the output. The module will indicate a fault
condition when the output current limit threshold is
exceeded. The default response from an output current fault
is an immediate shutdown of the module. The module will
continuously check for the presence of the fault condition,
and if the fault condition no longer exists the module will be
re-enabled. PMBus commands can be used to configure the
current limit threshold and the response of the module to
the fault condition.
Thermal Overload Protection
The NDM2Z-12 module includes a thermal sensor that
measures the temperature of the module and indicates a
fault when the temperature exceeds a preset limit. The
default response from a temperature fault is an
immediate shutdown of the module. The module will
continuously check for the fault condition and once the fault
has cleared the module will be re-enabled. PMBus
commands can be used to configure the thermal
protection threshold and the response of the module to the
fault condition. Permanent damage to the module may
result if the thermal limit is set too high.
SMBUS
SMBus Communications
The NDM2Z-12 module provides a SMBus interface that
enables the user to configure the module operation as well
as monitor input and output parameters. The module can
be used with any standard 2-wire I2C host device, accepts
most standard PMBus commands, is compatible with SMBus
version 2.0 and includes an SALRT line to help mitigate
bandwidth limitations related to continuous fault
monitoring. It is recommended that CTRL be pulled low
while configuring the module with PMBus commands.
Pull-up resistors are required on the SMBus lines as
described in "RECOMMENDED OPERATING CONDITIONS".
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CUI Inc │ MODEL: NDM2Z-12H │ DESCRIPTION: AUTO COMPENSATED, DIGITAL DC-DC POL CONVERTER
SMBus Addresses
When communicating with multiple SMBus devices using the
SMBus interface, each device must have a unique address
so the host can distinguish between the devices. The
NDM2Z-12 module address can be set according to the
pin-strap options listed in Table 5; address values are
right-justified.
If additional module addresses are required, a resistor can
be connected to pin SA0 as shown in Table 6 to provide up
to 25 unique module addresses.
Table 5: Pin-strap SMBus Addressing
SA0
ADDRESS
HIGH
0x25
OPEN
0x24
LOW
0x23
Table 6: Single Resistor SMBus Addressing
RSA0 (kΩ)
ADDRESS
RSA0 (kΩ)
ADDRESS
10.0
0x64
34.8
0x71
11.0
0x65
38.3
0x72
12.1
0x66
42.2
0x73
13.3
0x67
46.4
0x74
14.7
0x68
51.1
0x75
16.2
0x69
56.2
0x76
17.8
0x6A
61.9
0x77
19.6
0x6B
68.1
0x78
21.5
0x6C
75.0
0x79
23.7
0x6D
82.5
0x7A
26.1
0x6E
90.9
0x7B
28.7
0x6F
100.0
0x7C
31.6
0x70
Monitoring Via SMBus
A system controller can be used to monitor the NDM2Z-12
module system parameters through the SMBus. Fault
conditions can be detected by monitoring the SALRT pin,
which will be asserted when pre-configured fault conditions
occur. Modules can also be monitored for power conversion
parameters including but not limited to the following:
•
•
•
•
•
•
Input voltage
Output voltage
Output current
Module temperature
Switching frequency
Duty cycle
date 11/07/2014 │ page 13 of 14
SINGLE WIRE COMMUNICATIONS
Digital-DC Bus
The DDC (Digital-DC Communication Bus) is used to
communicate between NDMxZ modules. This dedicated bus
provides the communication channel between modules for
features such as sequencing, fault spreading, and current
sharing. A pull-up resistor is required on the DDC as
defined in “RECOMMENDED OPERATING CONDITIONS”.
Snapshot™ Parameter Capture
The NDM2Z-12 module offers features that enable the user
to capture parametric data during normal operation or
following a fault. The Snapshot feature enables the user to
read status and parameter values via a block read transfer
through the SMBus. This can be done during normal
operation, although it should be noted that reading the 22
bytes will occupy the SMBus for up to 1400 μs.
The SNAPSHOT_CONTROL command enables the user to
store the snapshot parameters to flash memory in
response to a pending fault as well as to read the stored
data from flash memory after a fault has occurred.
Automatic writes to flash memory following a fault are
triggered when any fault threshold level is exceeded,
provided that the specific response to that fault is
to shut down (writing to flash memory is not allowed if the
module is configured to re-try following the specific fault
condition). It should also be noted that the input voltage to
the module must be maintained during the time when the
module is writing the data to flash memory; a process that
requires between 700 μs to 1400 μs depending on whether
the data is set up for a block write. Undesirable results may
be observed if the input voltage to the module drops too
low during this process. In the event that the module
experiences a fault and power is lost, the user can extract
the last SNAPSHOT parameters stored during the fault
by using the SMBus to transfer data from flash memory to
RAM and then using the SMBus to read data from RAM.
THERMAL CONSIDERATIONS
Mounting
Heat from the NDM2Z-12 module will be conducted through
the pins to the host board. Provisions must be made for the
host board to accommodate this additional heating.
Airflow
Airflow past the NDM2Z-12 module will assist in cooling
the module. Factors affecting the efficiency of the cooling
include the rate, direction and temperature of the airflow.
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CUI Inc │ MODEL: NDM2Z-12H │ DESCRIPTION: AUTO COMPENSATED, DIGITAL DC-DC POL CONVERTER
date 11/07/2014 │ page 14 of 14
REVISION HISTORY
rev.
date
0.9
12/12/2013
0.91
03/13/2014
0.92
11/07/2014
The revision history provided is for informational purposes only and is believed to be accurate.
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CUI Novum products use patented technology licensed from Power-One.
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CUI offers a two (2) year limited warranty. Complete warranty information is listed on our website.
CUI reserves the right to make changes to the product at any time without notice. Information provided by CUI is believed to be accurate and reliable. However, no responsibility is
assumed by CUI for its use, nor for any infringements of patents or other rights of third parties which may result from its use.
CUI products are not authorized or warranted for use as critical components in equipment that requires an extremely high level of reliability. A critical component is any component of a
life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness.
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