Stresses in excess of the maximum ratings can cause permanent damage to the device. Operation of the device is not implied at these or any other conditions
in excess of those given in the specification. Exposure to absolute maximum ratings can adversely affect device reliability.
Voltage Transformation Module
MT036 SERIES
vicorpower.com
Rev. 1.0
Page 1 of 11
SPECIFICATIONS
PART NUMBERING
MT
Voltage
Transformation
Module
036
Input
Voltage
Designator
A
Package
Size
120
Output
Voltage
Designator
(=V
OUT
x10)
M
010
Output
Current
Designator
(=I
OUT
)
F
P
Product Grade Temperatures (°C)
Grade
M=
Operating
Storage
Baseplate
F
= Slotted flange
T
= Transverse heat sink
[a]
[a]
Contact
Pin Style
P
= Through hole
-55 to +100 -65 to +125
factory
Input Specifications
Parameter
Input voltage range
Input dV/dt
Input overvoltage turn-on
Input overvoltage turn-off
Input current
No load power dissipation
(Conditions are at 36 Vin, full load, and 25°C baseplate unless otherwise specified)
Min
26
50.5
Typ
36
54.5
55.5
1.5
3.0
57.5
3.5
6.0
Max
50
1
Unit
Vdc
V/µs
Vdc
Vdc
Adc
W
Continuous
Low line to high line
Notes
Operable down to zero V with VC voltage applied
Output Specifications
Parameter
Output voltage
Rated DC current
Peak repetitive current
DC current limit
Short circuit protection set point
Current share accuracy
Efficiency
Load capacitance
Output overvoltage setpoint
Output ripple voltage (Typ)
No external bypass
10 µF bypass capacitor
Effective switching frequency
Line regulation
Load regulation
Transient response
Response time
Recovery time
(Conditions are at 36 Vin, full load, and 25°C baseplate unless otherwise specified)
Min
Typ
See Table 1
K
•
V
IN
– l
O
•
R
OUT NOM
0
100
150%
160%
47.4
5
10
Max
Unit
Vdc
Vdc
Adc
I
MAX
(A)
I
NOM
(A)
Adc
%
Note
No load
Full load
26 – 50 V
IN
See Table 1, Page 5
Max pulse width 1ms, max duty cycle 10%,
baseline power 50%
Module will shut down when current limit
is reached or exceeded
Module will shut down
See Parallel Operation on Page 8
See Table 2, Page 5
See Table 2 when used with PRM
110%
115%
V
OUT MAX
mV
mV
MHz
See Figures 2 and 5
See Figure 6
Model dependent
V
OUT
= K•V
IN
at no load, See Table 1
mΩ
See Table 1
50
2
2.5
0.99K
R
OUTMIN
200
1
3.0
K
250
20
3.6
101K
R
OUTMAX
ns
µs
See Figures 7 and 8
See Figures 7 and 8
Voltage Transformation Module
MT036 SERIES
vicorpower.com
Rev. 1.0
Page 2 of 11
SPECIFICATIONS (CONT.)
TYPICAL WAVEFORMS & PLOTS
Ripple vs. Output Current
120
Output Ripple (mVpk-pk)
100
80
60
40
20
0
0
1
2
3
4
5
6
7
8
9
10
Output Current (A)
Figure 1
—
Representative input reflected ripple current at full load
(MT036A120M010FP)
Figure 2
—
Sample output voltage ripple vs. output current with no POL
bypass capacitance. (MT036A120M010FP)
Efficiency vs. Output Current
96
94
6
Power Dissipation
Power Dissipation (W)
5.5
5
4.5
4
3.5
3
2.5
2
0
1
2
3
4
5
6
7
8
9
10
Efficiency (%)
92
90
88
86
84
0
1
2
3
4
5
6
7
8
9
10
Output Current (A)
Output Current (A)
Figure 3
—
Representative efficiency vs. output current. (MT036A120M010FP)
Figure 4
—
Example power dissipation vs. output current. (MT036A120M010FP)
Figure 5
—
Sample output voltage ripple at full load; with no POL bypass
capacitance. (MT036A120M010FP)
Figure 6
—
Sample output voltage ripple at full load with 4.7 µF ceramic POL
bypass capacitance and 20 nH distribution inductance. (MT036A120M010FP)
Voltage Transformation Module
MT036 SERIES
vicorpower.com
Rev. 1.0
Page 3 of 11
SPECIFICATIONS (CONT.)
TYPICAL WAVEFORMS
Figure 7
—
Example load step with 100 µF input capacitance and no output
capacitance. (MT036A120M010FP)
Figure 8
—
Example load step with 100 µF input capacitance and no output
capacitance. (MT036A120M010FP)
Voltage Transformation Module
MT036 SERIES
vicorpower.com
Rev. 1.0
Page 4 of 11
SPECIFICATIONS (CONT.)
Military Cots VTM Family Part Numbers and Ranges
Part Number
MT036A011M100FP
MT036A015M080FP
MT036A022M055FP
MT036A030M040FP
MT036A045M027FP
MT036A060M020FP
MT036A072M017FP
MT036A090M013FP
MT036A120M010FP
MT036A180M007FP
MT036A240M005FP
MT036A360M003FP
Table 1
— VTM part numbers
[a]
K-Factor
1/32
1/24
1/16
1/12
1/8
1/6
1/5
1/4
1/3
1/2
2/3
1
Rated Output
Current (A)
100
80
55
40
27
20
16.6
13.3
10.0
6.7
5.0
3.3
No Load Output Voltage (Vdc)
@26 Vin
0.82
1.1
1.63
2.2
3.3
4.3
6.4
[a]
6.5
8.7
13
17.4
26
@ 50 Vin
1.55
2.0
3.1
4.1
6.2
8.3
10
12.5
16.6
25
33
50
Min
0.5
1.0
1.4
1.45
3.5
5.0
6.0
6.9
25
27.5
49.3
140
Rout (mΩ)
Nom
0.85
1.25
1.75
2.4
5.1
8.0
9.6
9.3
31
35.7
70.6
170
Max
1.3
1.5
2.0
3.4
6.6
10
12
11.6
35
46.4
91.8
200
Low line input voltage 32 V
Typical Full Load Efficiency at nom Vout (%) Typical Half Load Efficiency at nom Vout (%) Maximum Load Capacitance (µF)
89.5
92
94
94
95.3
95.3
96.5
96.3
95.5
96.0
95.0
96
91.5
94
94.5
95.0
96.5
96.8
96.5
95.5
95.5
95.2
94.8
96
48128
27072
12032
6768
3008
1692
1175
752
423
188
106
47
Part Number
MT036A011M100FP
MT036A015M080FP
MT036A022M055FP
MT036A030M040FP
MT036A045M027FP
MT036A060M020FP
MT036A072M017FP
MT036A090M013FP
MT036A120M010FP
MT036A180M007FP
MT036A240M005FP
MT036A360M003FP
Table 2
— Typical efficiency and maximum load capacitance, by part number
Control Pin Functions
VC – VTM Control
The VC port is multiplexed. It receives the initial V
CC
voltage from an
upstream PRM, synchronizing the output rise of the VTM with the
output rise of the PRM. Additionally, the VC port provides feedback to
the PRM to compensate for the VTM output resistance. In typical
applications using VTMs powered from PRMs, the PRM’s VC port
should be connected to the VTM VC port.
In applications where a VTM is being used without a PRM, 14 V must
be supplied to the VC port for as long as the input voltage is below 26 V
and for 10 ms after the input voltage has reached or exceeded 26 V. The
VTM is not designed for extended operation below 26 V. The VC port
should only be used to provide V
CC
voltage to the VTM during startup.
PC – Primary Control
The Primary Control (PC) port is a multifunction port for controlling the
VTM as follows:
Disable – If PC is left floating, the VTM output is enabled. To
disable the output, the PC port must be pulled lower than 2.4 V,
referenced to -In. Optocouplers, open collector transistors or relays
can be used to control the PC port. Once disabled, 14 V must be
re-applied to the VC port to restart the VTM.
Primary Auxiliary Supply – The PC port can source up to 2.4 mA
Everyone must be familiar with GPS. Everyone should know that decoding GPS is not difficult and the principle is very simple. Anyway, let's introduce the process and related knowledge in detail. GPS i...
MP3 chargers are one of the most easily damaged accessories. After repairing many types of chargers, I found that they basically all use switching power supply circuits, and the circuit structures are...
When I use this function to write the south bridge address, it will cause the system to restart, using ICOP's DX processor: void WriteSouthBridge(unsigned char idx, DWORD val) { __asm { push edx mov d...
[font=微软雅黑]From now until October 24th[/font] [font=微软雅黑]Buy [b]2[/b] units of F-101/F-101Kit and get a free stylish ultra-thin wireless mouse[/font] [font=微软雅黑]Buy [b]1[/b] unit of F-106 and get a fr...
Hardware designers have begun to adopt FPGA technology in high-performance DSP designs because it can provide 10-100 times faster computing than PC-based or microcontroller-based solutions. Previou...[Details]
As a wireless broadband metropolitan area network standard, WiMAX technology has greater advantages than previous 3.5GHz MMDS products in terms of non-line-of-sight transmission and spectrum utiliz...[Details]
When the WDP500-2A plane grating monochromator is used to test the emission wavelength of a high-power laser diode at different currents, the matching of the laser diode has the disadvantages of lo...[Details]
This article discusses how to wake up a touch-sensitive device such as a tablet without touching the device, using basic gesture recognition and novel proximity sensors. The article discusses the p...[Details]
1 Introduction
As an emerging microfabrication technology, micro-electromechanical system (MEMS) technology has begun to be applied in various fields. It can integrate functions such as inform...[Details]
0 Introduction
With the rise and continuous improvement of the solid-state lighting industry, light-emitting diodes (LEDs) have become an alternative lighting technology and are gr...[Details]
Flooded Batteries
This battery developed in Germany can be used to power flashlights, strobe lights and toys as long as it is filled with water. This battery can be stored for 50 years and can...[Details]
VP2188 is a color STN LCD module produced by Jingdian Pengyuan. This module is a dot matrix transmissive color STN display screen with a color scale of 65 k colors and white LED backlight. Its core...[Details]
Introduction
Liquid crystal, as a display device, is widely used in low-power products such as instruments, meters, and electronic equipment with its unique advantages. In the past, the displ...[Details]
OC faults may be the most frequent and the most frequent of all faults in the inverter. They alarm during the startup process, during the shutdown process, during operation, and even when powered o...[Details]
Preface
In recent years, white light LEDs have gradually replaced incandescent bulbs and fluorescent lamps because they have unparalleled advantages over traditional light sources in terms...[Details]
Since AC mains power may experience power outages, voltage sags and surges, continuous undervoltage and overvoltage, and frequency fluctuations during supply, these factors will affect the continuous ...[Details]
0 Introduction
With the rapid development of social economy and science and technology, electric locomotives, subways and electric vehicles will be widely used. The power conversion and cont...[Details]
1 Introduction
With the rapid economic development, my country's electricity demand has been growing at a rate of more than 20% per year. According to the current economic development trend an...[Details]
introduction
At present, the research on micron and nanotechnology is very active, which has led to the rapid development of microtechnology and micro-mechanical electronic system (MEMS) t...[Details]
NXP MCU
京公网安备 11010802033920号
EEWORLD
