ASTEC AIF40C300-L/N-L/-NTL

Technical Reference Notes
AIF12W300 DC-DC Series
AIF12W300, 600W, DC-DC Converter Module
The single output AIF is an isolated, single output DC to DC converter module, providing up to 600W output with a maximum
baseplate operating temperature of 100°C with no derating. The AIF features full safety isolated low voltage secondary side
control and Astec Linear Programming (ALP™) or through I2C bus for convenient adjustment of the module's parameters.
Electrical Parameters
Special Features
•
•
•
•
•
•
•
•
•
600W continuous power at 100°C baseplate
temperature
108W/in3 (6.6W/cm3)
High efficiency – 91.8% typical
Low output ripple and noise
Positive and Negative Enable function
Excellent transient response
OVP, OCP, V Adj control with ALPTM analog
mode linear control, or through I2C bus for
digital mode control.
Paralleable with accurate current sharing
Switching Frequency 400KHz
Input
Input range
Input Surge
Efficiency
250 - 420 VDC
500V / 100ms
91.8% (Typical)
Output
Regulation
Noise / Ripple
0.2% typical down to no load
480mV typical
Control
Voltage Adjust
Enable
Current Limit Adjust
Over Voltage
Protection Adjust
80 to 120%
TTL compatible
(positive & negative enable
options)
20% to 100%
110% to 150% VO
Safety
UL, cUL
TUV
60950 Recognized
EN60950 Licensed
Environmental Specifications
-20°C to 100°C Operating Baseplate Temperature
-55°C to 125°C Storage Temperature
MTBF > 0.3Mhours
Pb-free reflow compatible and ROHS Compliant
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JUNE 2006
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Technical Reference Notes
AIF12W300 DC-DC Series
Electrical Specifications
STANDARD TEST CONDITION on a single unit, unless otherwise indicated, electrical specifications apply over all
operating input voltage and temperature conditions.
Tamb
Vin
Enable
CLK IN
CLK OUT
CSHARE
Iout
AUX OUTPUT
-Sense
V ADJ
C MON
TEMP MON
C LIM ADJ
OVP ADJ
PG/ID
I/P Cap requirement
25°C
300 V± 2%
Open
Open
Open
Open
75% Io max ± 2%
Open
connect to –Vout
Open
Open
Open
Open
Open
Open
68µF/450V min.
ABSOLUTE MAXIMUM RATINGS
Stresses in excess of the absolute maximum ratings can cause permanent damage to the device. These are absolute stress
ratings only. Functional operation of the device is not implied at these or any other conditions in excess of those given in the
operational sections of the IPS. Exposure to absolute maximum ratings for extended periods can adversely affect device
reliability.
Parameter
Input Voltage:
Continuous:
Transient (100ms)
Operating Baseplate Temperature
Start up Baseplate Temperature
Storage Temperature
Operating Humidity
I/O Isolation
MODEL: AIF12W300 SERIES
JUNE 2006
Symbol
Min
Typ
Max
Unit
VI
VI, trans
Tc
TSTG
-
250
-
420
500
100
100
125
95
-
Vdc
Vdc
°C
°C
°C
%
Vdc
-20
-40
-55
15
2700
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Technical Reference Notes
AIF12W300 DC-DC Series
INPUT SPECIFICATIONS
Parameter
Operating Input Voltage
Undervoltage Threshold
(IO = 10% IO max)
Turn-on point
Turn-off point
Input Current 1
(VI = VI min, IO = IO max,
VO = VO nom)
(VI = 0 to VI max, IO = IO max,
VO = VO nom)
Input Reflected Ripple Current 2
(5Hz to 20MHz: 12µH source
impedance: Tamb = 25°C)
Inrush Transient 3
Break Regulation
CLK IN
Frequency
Voltage Level
(internal ac coupled)
Enable
Positive Logic
Low Logic - Module Off
High Logic - Module On
(Enable pin opened)
Enable Low Sourced Current
(Venable = 0.7V)
Turn-On Delay
No load input power
Turn-On Time
(IO = IO max ; VO within 1%)
(No external O/P capacitance)
Input Capacitance
MODEL: AIF12W300 SERIES
JUNE 2006
Symbol
VI
Min
250
Typ
300
Max
420
Unit
Vdc
-
205
175
-
245
215
V
V
II max
-
-
2.8
A
II max
-
-
3.4
A
II
-
30
-
mApk-pk
I2t
-
-
215
2.8
245
A2s
V
-
720
3.3
800
-
880
5.5
kHz
Vpk-pk
Venable
Venable
0
2
-
0.7
10
V
V
-
-
-
150
µA
-
-
-
380
5
mS
W
-
-
-
650
mS
-
-
0.6
0.8
µF
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Technical Reference Notes
AIF12W300 DC-DC Series
OUTPUT SPECIFICATIONS
Parameter
Output Voltage Setpoint
(VI min to VI max:
IO = IO max ; Tamb = 25°C )
Output Regulation:
Line
Symbol
VO set
Min
47.52
Typ
48
Max
48.48
Unit
V
-
-
-
0.2
%
Load
Output Voltage Adjust 4, 5
Vadj = 0V
-
-
-
0.2
%
-
78
80
82
%VO
Vadj = 2V
Output Ripple and Noise
Peak-to-Peak (5 Hz to 20MHz)
-
118
120
122
%VO
-
-
110
480
mVpk-pk
External Load Capacitance
Switching Frequency
Output Power
Efficiency
(VI = VI nom, IO = IO max, Tamb = 25°C)
Output Current
Output Current-limit Inception (Hiccup)
(VO = 97% VO set nom)
Output Current Limit Adjust 5
Output Current Monitor
Imon at IO max
Monitored IO Range
Imon Compliance Voltage
Current Share Accuracy 6
(Cshare connected together,
IO ≥ 80%IO max)
PO
360
-
400
-
2000
440
600
µF
kHz
W
IO
90
0
91.8
-
12.5
%
A
IO
-
105
20
-
120
100
%IO
%IO
-
0.9
20
-
1.0
-
1.1
100
5.0
mA
%IO max
V
-
-
±3
±5
%I avg
No. of Parallel Unit
Over Current Protection Level
(VO dropped to 97% of VO nom)
Over Voltage Protection Level
Over Voltage Protection Adjust 5
Over Temperature Protection Trip Point
(Baseplate temperature)
Internal Temperature Monitor
Temperature Coefficient
Source Impedance
Temperature Coefficient
(TC = -40°C to 100°C)
-
-
-
10
pcs
-
105
120
120
110
125
-
115
130
150
%IO max
%VO
%VO
-
105
-
120
°C
-
9.8
-
10.0
1.0
10.2
-
mV/°C
kΩ
-
-
-
0.02
%VO/°C
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JUNE 2006
max
max
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Technical Reference Notes
AIF12W300 DC-DC Series
OUTPUT SPECIFICATIONS (continued)
Parameter
Step-load Excursion
(25% to 75% load change @ 1A/µS,
recovery to 1%VO; VI = VI nom;
Tamb = 25°C)
Output Overshoot
Output Undershoot
Step Load Response
(25% to 75% load change @ 1A/µS,
recovery to 1%VO; VI = VI nom;
Tamb = 25°C; measure from end of
transition)
Turn-on Output Voltage Overshoot
(IO = IO max ; Tamb = 25°C;
no external O/P capacitor)
Short Circuit Current
(Hiccup Mode)
CLK OUT
Frequency
Voltage Level (internal ac coupled)
No. of Fan Out Unit
Turn-Off Negative Voltage
(resistive loading, wire length of
10cm)
AUX Output Voltage
AUX Output Current 7
AUX Output Voltage Ripple and Noise
Power Good Monitor / Identification
PG/ID Low
(Power Fault, Isink ≤ 10mA)
PG/ID Internal Pull-up
Resistance to VO
Symbol
Min
Typ
Max
Unit
-
-
-
2.4
2.4
V
V
-
-
-
250
µS
-
-
3
5
%VO
-
-
-
150
-
720
3.3
-
800
-
880
5.5
2
kHz
Vpk-pk
pcs
-
-
-
-0.7
V
-
10.5
-
12
-
13.5
10
600
V
mA
mV
-
-
-
0.2
V
-
46
47
48
kΩ
%IO
max
Notes: 1. An input line fuse is recommended for use (e.g. Littelfuse type, 10A 250V FB).
2. External input capacitance required. See Figure 1 for the Input Reflected-Ripple Current Test Setup.
Measure input reflected-ripple current with a simulated source inductance of 12µH.
3. See Figure 2 for the Inrush Current Test Setup. Measure input inrush current with a simulated source
inductance of 12µH and input bulk capacitor of 68µF/450Vmin must always be added.
4. The combination of remote sense and trim do not exceed a total of 0.5V.
5. Refer to Basic Operation and Features section.
6. See Figure 3 for modules in parallel connection.
7. The AUX output pin does not allow for any short circuit and OCP testing.
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Technical Reference Notes
AIF12W300 DC-DC Series
Electrical Specifications (continued)
ISOLATION SPECIFICATIONS
Parameter
Isolation Capacitance
Isolation Resistance
Device
Symbol
All
All
-
Min
Typ
Max
Unit
10
300
-
-
PF
MΩ
SAFETY AGENCY
Parameter
Safety Approval
Device
All
UL/cUL 60950, 3rd Edition – Recognized
EN 60950 through TUV
SHOCK AND VIBRATION
Vibration test
Endurance random vibration (non-operating)
Random vibration shall be applied at the following test condition:
Frequency range
PSD
Acceleration
Duration
10 – 200Hz; 200 – 2000Hz
0.01g2/Hz; 0.003g2/Hz
2.5g RMS (typical level)
20 mins per axis
Endurance random vibration (operating)
Random vibration shall be applied at the following test condition with the unit at operating mode at nominal lines and full load
condition, with POK monitored:
Frequency range
PSD
Acceleration
Duration
10 – 500Hz
0.002g2/Hz flat
1g RMS
20 mins per axis
Shock test
The non-operating test condition is selected as typical of:
Acceleration
Pulse
Duration
Directions
MODEL: AIF12W300 SERIES
JUNE 2006
30g
Halfsine
6ms minimum
all 6 faces, 3 times in each positive
and negative directions
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Technical Reference Notes
AIF12W300 DC-DC Series
Electrical Specifications (continued)
Shock test
The operating test condition is selected as typical of:
Acceleration
Pulse
Duration
Directions
4g
Halfsine
22ms minimum
all 6 faces, 3 times in each positive
and negative directions
ESD
Contact discharge
Air discharge
6KV
8KV
EMC (CONDUCTED)
FCC Class A and CISPR22 Class A – This is a system test and not a component level test. See Figure 4 for EMI Filter
Schematic.
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Technical Reference Notes
AIF12W300 DC-DC Series
Electrical Specifications (continued)
Figure 1. Input Reflected-Ripple Test Setup
Figure 2. Inrush Current Test Setup
Figure 1. Input Reflected-Ripple Current Test Setup
Figure 2. Inrush Current Test Setup
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Technical Reference Notes
AIF12W300 DC-DC Series
Electrical Specifications (continued)
Single Module Operation
Parallel Module Operation
Figure 3. Module Connections for Single and Parallel Operation
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Technical Reference Notes
AIF12W300 DC-DC Series
Electrical Specifications (continued)
Figure 4. EMI Filter Schematic for AIF Series
Figure 5. EMI Filter Scan (without Filter)
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Technical Reference Notes
AIF12W300 DC-DC Series
Performance Curves
AIF12W300
Efficiency vs. Output Current
Pow er Dissipation vs. Output Current
70
90%
60
Efficiency [%]
85%
80%
75%
70%
Vin = 250Vdc
65%
Vin = 300Vdc
60%
Vin = 420Vdc
Power Dissipation [W]
95%
50
40
30
20
Vin = 250Vdc
10
Vin = 300Vdc
Vin = 420Vdc
0
55%
0
2
4
6
8
Output Current [A]
10
12
0
2
4
6
8
Output Current [A]
10
Figure 6. Efficiency vs. Load Current at Ambient
Temperature (TA) = 25°C.
Figure 7. Power Dissipation vs. Load Current at
Ambient Temperature (TA) = 25°C.
Figure 8. Output Ripple Waveform, Vin = 300V,
Io = 12.5A, at Ambient Temperature (TA) = 25°C.
Figure 9. Clock Out Waveform, Vin = 300V, Io =
12.5A, at Ambient Temperature (TA) = 25°C.
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Technical Reference Notes
AIF12W300 DC-DC Series
Performance Curves
AIF12W300 (continued)
Figure 10. Transient Response-Vout Deviation (Hi-Lo)
at Ambient Temperature (TA) = 25°C.
Figure 11. Transient Response-Vout Deviation (Lo-Hi)
at Ambient Temperature (TA) = 25°C.
Figure 12. Turn-on Time (Enable to Output) at Ambient
Temperature (TA) = 25°C.
Figure 13. Turn-on Time (Input to Output) at Ambient
Temperature (TA) = 25°C.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features
Remote Sense (+SENSE, -SENSE)
Connect the +SENSE and –SENSE pins of the module
directly to the load to allow the module to compensate for
the voltage drop across the conductors carrying the load
current. If remote sensing is not required (for example if
the load is close to the module) the sense pins should be
connected directly to the module’s output pins to ensure
accurate regulation.
Note: If the sense leads fail open circuit, the module will
revert to local sense at the output pins. Incorrect
connection of sense leads may damage the module.
Remote Sense compensation at nominal VO only.
Enable Control (ENABLE)
The enable pin is a TTL compatible input used to turn the
output of the module on or off. The output is enabled when
the ENABLE pin open or driven to a logic high >2V, and
disabled when the ENABLE pin is connected to –SENSE
or driven to a logic low of < 0.7V.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
Output Voltage Adjustment (V ADJ)
The output voltage of the module may be accurately adjusted by up -20%, +20% of the nominal factory set output. Adjustment
is carried out using either an external voltage source (0 to 2V, capable of sinking 1mA) or resistor (0 to 2K) connected between
VADJ and –SENSE.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
Current Limit Adjustment (C LIM ADJ)
A constant current limiting circuit protects the module
under overload or short circuit conditions. With the C LIM
ADJ pin left unconnected, the current limit is factory set to
115% of the module’s rated output. Current limit may be
adjusted across the range from 20% to 100% using an
external voltage source (0.8 to 4V, capable of sinking
1mA) or a resistor (800R to 4K) connected between
C LIM ADJ and –SENSE.
Overvoltage Protection Adjustment (OVP ADJ)
An independent overvoltage circuit monitors the module’s
output pins and will shut the module down in the event of
an internal or external fault which causes the output
voltage to rise above the preset limit. The module is reset
by removing and re-applying the input power or toggle the
ENABLE OFF/ON.
The overvoltage set point may be adjusted between 20%
and 50% above the output voltage (VO), and automatically
track adjustments made to the output voltage using V ADJ.
OVP ADJ should be used to increase the OVP margin
when the voltage drop between power output pins and
remote sense is more than 0.2V.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
Power Good / Identification (PG/ID)
This pin provides an indication that the module’s converters are working, and can also be used to identify the factory set output
voltage of the module. The PG/ID pin goes high to the level of the output voltage (VO) to indicate that the module is operating
and delivering power. The output goes low if the converters stop operating due to a fault such as an overtemperature or
overvoltage condition. The PG/ID pin will also go low if the module is disabled via the ENABLE pin or under light load
condition.
The resistance between the PG/ID pin and the +ve output of the module can be used to identify the module with no power
applied according to the table:
Model Number
AIF12W300-L
AIF12W300N-L
AIF12W300-NTL
AIF12W300N-NTL
MODEL: AIF12W300 SERIES
JUNE 2006
Resistance (kΩ)
47
47
47
47
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
Clock Signals (CLK IN, CLK OUT)
The module’s internal clock is accurate and stable over its full operating range and synchronization is not normally required,
but it can reduce noise in paralleled systems.
Clock signals can be wired in series (the CLK OUT pin of one module to the CLK IN pin of the next etc) in which case all the
modules will be synchronized with the first module in the chain. Alternatively, an external clock signal of 5Vpk-pk at 800KHz
±10% can be connected to the CLK IN pins of all the modules.
If the clock input to any module fails, the module will automatically switch back to its internal clock and will continue to
operate normally. The CLK IN and CLK OUT signals are AC coupled, so any module can clock another module regardless of
polarity.
Current Share (CSHARE)
To ensure that all modules in a parallel system accurately share current, the C SHARE pins on each module should be
connected together.
The voltage on the C SHARE pins represents the average load current per module. Each module compares this average with its
own current and adjusts its output voltage to correct the error. In this way the module maintains accurate current sharing.
Note: The –SENSE and +SENSE pins of each module must also be connected together to ensure accurate current sharing.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
Current Monitoring (C MON)
The C MON pin provides an indication of the amount of
current supplied by the module. The output of the C MON
pin is a current source proportional to the output current of
the module, where 0.2 to 1mA = 20 to 100% Iorated.
The C MON output can be paralleled with C MON outputs
from other modules to indicate the total current supplied in
a paralleled system.
Temperature Monitoring (TEMP MON)
The TEMP MON pin provides an indication of the
module’s internal temperature. The voltage at the TEMP
MON pin is proportional to the temperature of the module
baseplate at 10mV per °C, where:
Module temperature (°C) = (Vtemp mon X 100) – 273
The temperature monitor signal can be used by thermal
management systems (e.g. to control a variable speed fan).
It can also be used for overtemperature warning circuits
and for thermal design verification of prototype power
supplies and heatsink.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
Break Regulation
AIF12W300–Series modules are designed to deliver full
rate output current at up to 0.5V above VO nom at the
minimum specified input voltage.
I2C Digital Control (DCS, I2C CLK, I2C DATA)
The module shall be capable to be controlled by I2C
interface, which is SMBus compatible, via I2C CLK and
I2C DATA pins. These two pins share the same pin
location of CLIM ADJ and V ADJ pins respectively.
Digital control is selected when Digital Control Select
(DCS) pin voltage is between 2V to 4V. When digital
control is selected, analog adjust pin function is disabled.
DCS signal shall only be applied when the module is
powered off or disabled. An external 10k pull-up resistor is
necessary for each I2C CLK, and I2C DATA pin, for
100kHz I2C bus frequency.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
I2C COMMUNICATION PROTOCOL
1. Command word
Command word is sent by master system to inform slave device that what kind of operation the master like to do. It is a 16-bit
data. Bit 0 to bit 9 indicate the data need to transfer (e.g. the value of OV_ADJ). As there are two different lengths of data, one
is 8-bit and the other is 10-bit. So, if 10-bit data is transmitting/receiving, whole 10 bits (DATA9 – DATA0) will be used. In 8
bits case, only the least significant 8 bits (DATA7 – DATA0) will be used. The two bits (DATA9 and DATA8) will be cleared.
The 5 bits (REG4 – REG0) indicate which command needs to. When the master requests data from the slave, the DATA9DATA0 bits should be cleared. And during setting the four information items (Model Name, Serial No., Firmware Version,
Model Revision), DATA9-DATA8 should be cleared and is followed by the actual data.
The format of the 16-bits command word is as follow:
Bit 15
DSR
Bit 8
REG4
REG3
REG2
REG1
REG0
DATA9
Bit 7
DATA7
DATA8
Bit 0
DATA6
DATA5
DATA4
DATA3
DATA2
DATA1
DATA0
The DSR (Data Set Read) bit controls read/write of data. If the master send a 0 (write operation) for this bit, the slave device
will get the command register and data. And then set the value of the corresponding command register. If the master sends a 1
(read operation) for this bit, the slave device will get the current value of the corresponding command register and send it to the
master.
The table below shows the register mapping:
Command Register
MODEL_NO (read/write*)
SERIAL_NO (read/write*)
FIRMWARE_VER (read/write*)
MODEL_REV (read/write*)
SLAVE_ADDRESS (read/write)
OVP_ADJ (read/write)
V_ADJ (read/write)
CLIM_ADJ (read/write)
TMON (read only)
VOUT (read only)
CMON (read only)
RESET (write only)
LOCK (write only*)
UNLOCK (write only*)
Coding (REG4 – REG0)
00000
00001
00010
00011
00100
00101
00110
00111
01000
01001
01010
01111
10000
10001
* Remark: write functions only used to production.
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Technical Reference Notes
AIF12W300 DC-DC Series
I2C COMMUNICATION PROTOCOL (continued)
2. Data Transfer Structure on I2C Bus
Terms
Stt
Sadd
Ack
Bt-H
Bt-L
StD(1st, 2nd,…nth)
Stp
Description
Start bit
Slave address
Acknowledge
Higher byte
Lower byte
String of bytes(1st byte, 2nd byte,……nth byte)
Stop Bit
No. of bits
1
8
1
8
8
8
1
In the block diagram below, gray boxes indicate master-send signal; white boxes indicate slave-send signal.
Master
Slave
2.1 Set data to slave
SCL
SDA
A7 A6 A5 A4 A3 A2 A1 A0
D7 D6 D5 D4 D3 D2 D1 D0
D7 D6 D5 D4 D3 D2 D1 D0
Salve Address
Command byte (high)
Command byte (low)
Stop bit
Start bit
Wait for ack. signal
Fig 1.1 SCL and SDA signal in write mode.
S
SAdd
Ack
Bt-H (command)
Ack
Bt-L (command)
Ack
Stp
Fig 1.2 Block diagram of write mode.
Procedures:
1. The master device gives a Start condition via SDA.
2. Master sends the 8-bit slave address in which bit 0 of it should be 0 (0 indicate a write condition to slave) via SDA.
3. The addressed slave device give out acknowledge via SDA.
4. The master sends the high byte of command code via SDA.
5. The slave give out acknowledge via SDA.
6. The master sends the low byte of command code via SDA.
7. Slave gives out acknowledge after receiving the last byte.
8. Master gives a STOP condition via SDA to stop the transaction.
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Technical Reference Notes
AIF12W300 DC-DC Series
SCL
SDA
A7 A6 A5 A4 A3 A2 A1 A0
D7 D6 D5 D4 D3 D2 D1 D0
D7 D6 D5 D4 D3 D2 D1 D0
Salve Address
Command byte (high)
Command byte (low)
Stop bit
Start bit
Wait for ack. signal
SCL
SDA
A7 A6 A5 A4 A3 A2 A1 A0
D7 D6 D5 D4 D3 D2 D1 D0
D7 D6 D5 D4 D3 D2 D1 D0
Salve Address
Data byte receive (high)
Data byte receive (low)
Stop bit
Start bit
Give back NO ack. signal
Give back ack. signal
Fig. 2.1 SCL and SDA signal of read mode (2 bytes of data read).
S
SAdd
Ack
Bt-H (command)
S
SAdd
Ack
Bt-H (data)
Ack
Ack
Bt-L (command)
Bt-L (data)
Ack
Ack
Stp
Stp
Fig. 2.2 Block diagram of read mode (2 bytes of data read).
2.2 Read data from slave (2-byte data)
Procedures:
1. The master device gives out a start condition on SDA.
2. Master sends the 8 bits slave address which bit 0 of it should be 0 (0 indicates write mode for slave) via SDA.
3. The addressed slave device gives back acknowledge via SDA.
4. Master sends out the high byte of the 2-bytes command word.
5. Slave device gives back acknowledge again.
6. Master sends out the low byte of the 2-bytes command word.
7. Slave device gives back acknowledge again.
8. Master sends out a stop condition to prepare for the next transaction.
9. Master gives out a start condition again for the next transaction.
10. Master sends the 8 bits slave address which bit 0 of it should be 1(1 indicates read mode for slave) via SDA.
11. Slave give back an acknowledge.
12. Slave then sends out the high byte of desired data.
13. Master gives back acknowledge to slave.
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Technical Reference Notes
AIF12W300 DC-DC Series
14. Slave sends the low byte of the desired data.
SCL
SDA
A7 A6 A5 A4 A3 A2 A1 A0
D7 D6 D5 D4 D3 D2 D1 D0
D7 D6 D5 D4 D3 D2 D1 D0
Salve Address
Command byte (high)
Command byte (low)
Stop bit
Start bit
Give back ack. signal
SCL
……
SDA
A7 A6 A5 A4 A3 A2 A1 A0
D7 D6 D5 D4 D3 D2 D1 D0
……
String Data (1st) receive
Salve Address
D7 D6 D5 D4 D3 D2 D1 D0
String Data (last byte)
receive
Start bit
Stop bit
Give back NO ack. signal
Give back ack. signal
Fig 3.1 SCL and SDA signal of read mode (String of data).
S
SAdd
Ack
Bt-H (command)
Ack
S
SAdd
Ack
StD(1st)
StD(2nd)
Ack
Bt-L (command)
Ack
……
Ack
Stp
StD(nth)
Ack
Stp
Fig 3.1 Block diagram of read mode (String of data).
15. Master gives back acknowledge and sends out a stop condition to close the transaction.
2.3 Read data from slave (string of data)
Procedures:
1. The master device gives out a start condition on SDA.
2. Master sends the 8 bits slave address which bit 0 of it should be 0 (0 indicates write mode for slave) via SDA.
3. The addressed slave device gives back acknowledge via SDA.
4. Master sends out the high byte of the 2-bytes command word.
5. Slave device gives back acknowledge again.
6. Master sends out the low byte of the 2-bytes command word.
7. Slave device gives back acknowledge again.
8. Master sends out a stop condition to prepare for the next transaction.
9. Master gives out a start condition again for the next transaction.
10. Master sends the 8 bits slave address which bit 0 of it should be 1(1 indicates read mode for slave) via SDA.
11. Slave give back an acknowledge.
12. Slave then sends out the first byte of desired data.
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Technical Reference Notes
AIF12W300 DC-DC Series
13. Master gives back acknowledge to slave.
14. Repeat 12 and 13 until the end of bytes.
15. Master gives back acknowledge and sends out a stop condition to close the transaction.
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
DIGITAL CONTROL DEMO USER GUIDE
This Demo program is developed to test and evaluate I2C control features of AIF-300 DC/DC modules.
Equipment required:
1. One or more modules of AIF-300 series.
2. PC – Module interface hardware.
3. PC (with windows 98 / Me inside)
Hardware setup:
The picture shown below is the setup of the hardware.
PC - I2C
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AIF12W300 DC-DC Series
DIGITAL CONTROL DEMO USER GUIDE (continued)
Software Setup:
1. Click on the program “Ampss68.exe”. Then following dialog box shows:
2. Click on “Setup” and choose “Parallel Port Address”.
Then a new dialog box shows and enter the right value into it and click “OK”:
Enter the value in HEX here
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AIF12W300 DC-DC Series
3. Then click on “Setup” and choose “Pulse Constant”.
Also set the desired pulse constant value into the dialog box below and click “OK”:
Enter the value in DEC here
4. Select Module:
Enter the slave address of the module that you want to control:
Enter the corresponding
slave address here.
Note: “0” and “1” are the globe address of MMIIC. So, it can only perform “write” function when the UUT address is set
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Technical Reference Notes
AIF12W300 DC-DC Series
to 0 or 1.
5. Write Value:
These four items only used to
production. If needed to change
items clicked “Unlock” at first, and
then choose one item to change its
value.
Choose one of these four
items to change its value.
Click here when finished
choosing the one of the
above items.
Choose “Reset” to restore
all the default setting
except the slave address
“Lock” and “ Unlock” only used to
production. When needed to change items
“Model”, “Serial”, “Firmware”, “Model
rev” value, chose “Unlock”. When items
change is completed, clicked “Lock”.
Click on the circle beside the desired item that needs to be changed its value.
After choosing the desired item, click on “Write” below the items. Then a new dialog box shows (except “Reset” option).
Enter the
desired value
Fill the box with the new value and click “OK”. Or click “Cancel “ to cancel this operation.
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AIF12W300 DC-DC Series
6. Read Value:
Double click on the item box to read the corresponding value:
Double click the item
box to read its value.
7. Exit Program:
Click on “Setup” and choose “Exit” to exit the program.
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AIF12W300 DC-DC Series
Basic Operation and Features (continued)
PC-I2C INTERFACE CIRCUIT DIAGRAM
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
5V VCC2
10u
1k
1k
5V VCC1
10u
1k
1k
1k
1k
8
6N137
2N7002
100n
I2C DATA (AIF)
2N7002
2
6
2N7002
3
-SENSE (AIF)
5
7
1k
7
5
I2C SDA
3
2N7002
100n
2N7002
6
2
2N7002
6N137
8
I2C RTN
1k
1k
1k
1k
1k
2N7002
1k
8
6N137
100n
I2C CLK (AIF)
2N7002
2
6
2N7002
3
5
7
1k
7
5
I2C SCL
3
2N7002
2N7002
6
100n
2
2N7002
8
6N137
RECOMMENDED OPTO ISOLATION CIRCUIT
PARALLEL OPERATION WITH OPTO ISOLATION
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Technical Reference Notes
AIF12W300 DC-DC Series
Basic Operation and Features (continued)
DIGITAL CONTROL
The module shall be capable to be controlled by I2C interface, which is SMBus compatible, via I2C CLK and I2C DATA pins.
These two pins share the same pin location of CLIM ADJ and V ADJ pins respectively. Digital control is selected when Digital
Control Select (DCS) pin voltage is between 2V - 4V.
There are 7 command registers for read operation, 4 command registers for read/write operation and 1 command register for
write operation.
Command Register
MODEL_NO (read only)
SERIAL_NO (read only)
FIRMWARE_VER (read only)
MODEL_REV (read only)
SLAVE_ADDRESS (read/write)
OVP_ADJ (read/write)
V_ADJ (read/write)
CLIM_ADJ (read/write)
TMON (read only)
VOUT (read only)
CMON (read only)
RESET (write only)
Description
Read model name of the module
Read serial number on bar code label
Read firmware version
Read model revision
Read or set slave address of the module
Read or set overvoltage protection threshold of the module
Read or set output voltage of the module
Read or set current limit protection threshold of the module
Read baseplate temperature of the module
Read output voltage of the module
Read output current of the module
Reset all control parameters to factory setting
DIGITAL DATA CONVERSION
Each control and monitoring data is in 10-bit format. The data conversion formulae are as follows.
OVP_ADJ:
The range of the OVP_ADJ can be adjusted from 125% to 145% of VO (nom). The received/transmitted data is calculated by
the equation below.
Receive Data (from module to PC):
Input Data: MCU OVPadj (integer)
Output Data: OVPadj% (round to 1decimal place)
OVPadj% = 145% −
MCU OVPadj
× 20%
205
Transmit Data (from PC to module):
Input Data: OVPadj (round to 1 decimal place)
Output Data: MCU OVPadj (integer)
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MCU OVPadj =
145% - OVPadj%
× 205
20%
DIGITAL DATA CONVERSION (continued)
V_ADJ:
1. V_adj range between 80% to 120% module: (5Vo and above model)
The range of the V_ADJ can be adjusted from 80% to 120% of VO (nom). The received/transmitted data is calculated by the
equation below.
Receive Data (from module to PC):
Input Data: MCU Vadj (integer)
Output Data: Vadj% (round to 1decimal place)
Vadj% = 80% +
MCU Vadj
× 40%
410
Transmit Data (from PC to module):
Input Data: Vadj (round to 1 decimal place)
Output Data: MCU Vadj (integer)
MCU Vadj =
Vadj% - 80%
× 410
40%
2. V_adj range between 50% to 110% module: (Below 5Vo model)
The range of the V_ADJ can be adjusted from 50% to 110% of VO (nom). The received/transmitted data is calculated by the
equation below.
Vadj between 50% ~100%
Receive Data (from module to PC):
Input Data: MCU Vadj (integer)
Output Data: Vadj% (round to 1decimal place)
Vadj% = 50% +
MCU Vadj
× 50%
205
Transmit Data (from PC to module):
Input Data: Vadj (round to 1 decimal place)
Output Data: MCU Vadj (integer)
MCU Vadj =
MODEL: AIF12W300 SERIES
JUNE 2006
Vadj% - 50%
× 205
50%
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Technical Reference Notes
AIF12W300 DC-DC Series
DIGITAL DATA CONVERSION (continued)
Vadj between 100% ~110%.
Receive Data (from module to PC):
Input Data: MCU Vadj (integer)
Output Data: Vadj% (round to 1decimal place)
Vadj% = 100% +
MCU Vadj - 205
× 10%
205
Transmit Data (from PC to module):
Input Data: Vadj (round to 1 decimal place)
Output Data: MCU Vadj (integer)
MCU Vadj =
Vadj% - 90%
× 205
10%
CLIM_ADJ:
The range of the CLIM_ADJ can be adjusted from 0% to 102.5% or 110% of rated IO. The received/transmitted data is
calculated by the equation below.
Receive Data (from module to PC):
Input Data: MCU CLIMadj (integer)
Output Data: CLIMadj% (round to 1decimal place)
Case 1: MCU CLIMadj ≠ 841
CLIMadj% =
MCU CLIMadj
× 102.5%
840
Case 2: MCU CLIMadj >= 841
CLIMadj% = 110%
Transmit Data (from PC to module):
Input Data: CLIMadj (round to 1 decimal place)
Output Data: MCU CLIMadj (integer)
Case1: CLIMadj% ≠ 110%
Case2: CLIMadj% >= 110%
MCU CLIMadj =
CLIMadj%
× 840
102.5%
MCU CLIMadj = 841
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Technical Reference Notes
AIF12W300 DC-DC Series
DIGITAL DATA CONVERSION (continued)
TMON:
Baseplate temperature monitoring is a read only data. It is ranged from -40ºC to 120ºC. The temperature of module can be
calculated by the equation below:
Receive Data (from module to PC):
Input Data: MCU Tmon (integer)
Output Data: Baseplate Temperature in °C (round to 1 decimal place)
MCU Tmon
Baseplate Temperature in °C =
× 500 − 273
1024
VOUT:
Output Voltage is a read only data. The output voltage can be calculated by the equation below:
Receive Data (from module to PC):
Input Data: MCU Vout (integer)
Output Data: Output Voltage in %Vonom (round to 1 decimal place)
Output Voltage in %Vonom =
Module name
AIF120Y300-L/N-L/-NTL
AIF120F300-L/N-L/-NTL
AIF80A300-L/N-L/-NTL
AIF50B300-L/N-L/-NTL
AIF40C300-L/N-L/-NTL
AIF25H300-L/N-L/-NTL
AIF12W300-L/N-L/-NTL
MODEL: AIF12W300 SERIES
JUNE 2006
MCU Vout
× 100%
Vo _ REF
Vo_REF
369
676
813
820
830
820
820
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Technical Reference Notes
AIF12W300 DC-DC Series
DIGITAL DATA CONVERSION (continued)
CMON:
Current monitoring is a read only data. It is ranged from 0% to 100% of rated IO. The output current of module can be
calculated by the equation below:
Receive Data (from module to PC):
Input Data: MCU Cmon (round to 1 decimal place)
Output Data: Output Current Monitor in % IO max (integer)
Output Current Monitor in %Iomax =
MCU Cmon
× 100%
614
DEFAULT FACTORY SETTING
Control data
Slave address
OVP_ADJ
V_ADJ
CLIM_ADJ
MODEL: AIF12W300 SERIES
JUNE 2006
Factory Setting
0010100000 (A0h = 160) (8 bit addressing)
0011001101 (00CDh = 205) (125% of VO)
0011001101 (00CDh = 205) (100% of VO (nom) )
1111111111 (0349h = 841) (110% of rated IO)
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Technical Reference Notes
AIF12W300 DC-DC Series
Mechanical Specifications
Parameter
Dimension
Device
All
Weight
Symbol
L
W
H
All
Input
31. Positive
32. Negative
Min
-
Typ
4.60 [116.8]
2.40 [61.0]
0.50 [12.7]
Max
-
Unit
in [ mm ]
in [ mm ]
in [ mm ]
-
250
-
g [oz]
Suffix
NT
Suffix
PIN ASSIGNMENTS
Output
Control Pins
21. Positive
1. AUX
22. Positive
2. TEMP MON
23. Positive
3. C MON
24. Positive
4. C SHARE
25. Negative
5. CLK OUT
26. Negative
6. CLK IN
27. Negative
7. PG/ID
28. Negative
8. C LIM ADJ/I2C CLK
9. OVP ADJ/DCS
10. V ADJ/I2C DATA
11. ENABLE
12. - SENSE
PART NUMBERING SCHEME
AIF
“AIF” = Astec
Integrated Full
Brick Series
O/P CURRENT
xxx
12 = 12.5A
MODEL: AIF12W300 SERIES
JUNE 2006
O/P VOLTAGE
x
W = 48V
Vin
300
Enable
x
“N” = Negative
Logic Enable
300V DC
No suffix = Positive
Logic Enable
-
“-L” or “L” =
“-NT” = Non- Rohs Compliance
thread
mounting hole
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Technical Reference Notes
AIF12W300 DC-DC Series
Mechanical Specifications (continued)
Figure 14. Mechanical Outline Drawing
Figure 14. Mechanical Outline Drawing
Please call 1-888-41-ASTEC for further inquiries
or visit us at www.astecpower.com
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