Bel Power Solutions point-of-load converters are
recommended for use with regulated bus
converters in an Intermediate Bus Architecture
(IBA). The YNV05T16 non-isolated DC-DC
converter delivers up to 16 A of output current in
an industry-standard through hole SIP package.
Operating from a 3.0 – 5.5 V input, this converter
is an ideal choice for Intermediate Bus
Architectures where point-of-load power delivery
is generally a requirement. It provides an
extremely-tight regulated programmable output
voltage from 0.7525 V to 3.63 V.
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
RoHS lead-free solder and lead-solder-exempted
products are available
Delivers up to 16 A (53 W)
Industry-standard footprint and pinout
Single-in-Line Package (SIP): 2.0” x 0.575” x 0.315”
(50.8 x 14.59 x 8.00 mm)
Weight: 0.26 oz [7.28 g]
Synchronous buck converter topology
Start-up into pre-biased output
No minimum load required
Programmable output voltage via external resistor
Operating ambient temperature: -40 °C to 85 °C
Remote output sense
Remote ON/OFF (Positive or Negative)
Fixed-frequency operation
Auto-reset output overcurrent protection
Auto-reset overtemperature protection
High reliability, MTBF = TBD Million Hours
All materials meet UL94, V-0 flammability rating
Safety approved to UL/CSA 62368-1 and
EN/IEC 62368-1
The YNV05T16 converter provides exceptional
thermal performance, even in high temperature
environments with minimal airflow. This is
accomplished through the use of circuitry,
packaging, and processing techniques to achieve
ultra-high
efficiency,
excellent
thermal
management, and a very sleek body profile.
The sleek body profile and the preclusion of heat
sinks minimize impedance to system airflow, thus
enhancing cooling for both upstream and
downstream devices. The use of 100%
automation for assembly, coupled with advanced
power electronics and thermal design, results in a
product with extremely high reliability.
▪
▪
▪
▪
▪
Intermediate Bus Architectures
Telecommunications
Data Communications
Distributed Power Architectures
Servers, Workstations
▪
▪
High efficiency – no heat sink required
Reduces Total Solution Board Area
Minimizes Part Numbers in Inventory
▪
2
YNV05T16 DC-DC Converter
Conditions: TA = 25 ºC, Airflow = 200 LFM (1 m/s), Vin = 5 VDC, Vout = 0.7525 – 3.63 V, unless otherwise specified.
PARAMETER
NOTES
MIN
Continuous
-0.3
TYP
MAX
UNITS
6
VDC
ABSOLUTE MAXIMUM RATINGS
Input Voltage
Operating Ambient Temperature
-40
85
°C
Storage Temperature
-55
125
°C
3.63
VDC
0.5
VDC
FEATURE CHARACTERISTICS
Switching Frequency
300
Output Voltage Programming Range1
By external resistor, See Trim Table 1
0.7525
Remote Sense Compensation1
Turn-On Delay Time
2
kHz
Full resistive load
With Vin = (Converter Enabled, then Vin applied)
From Vin = Vin(min) to Vo=0.1* Vo(nom)
3.5
ms
With Enable (Vin = Vin(nom) applied, then enabled)
From enable to Vo= 0.1*Vo(nom)
3.5
ms
From 0.1*Vo(nom) to 0.9*Vo (nom)
3.5
ms
2
Rise time (Full resistive load)
ON/OFF Control (Positive Logic) 3
ON/OFF Control (Negative Logic)
3
Converter Off
-5
0.8
VDC
Converter On
2.4
5.5
VDC
Converter Off
2.4
5.5
VDC
Converter On
-5
0.8
VDC
For Vout 2.5 V
4.5
5.0
5.5
VDC
For Vout 2.5 V
Turn-on Threshold
3.0
5.0
5.5
VDC
2.05
2.15
VDC
Turn-off Threshold
1.75
INPUT CHARACTERISTICS
Operating Input Voltage Range
Input Under Voltage Lockout
1.9
VDC
Maximum Input Current
Vin = 4.5V, Iout = 16A
VOUT = 3.3 VDC
12.7
ADC
Vin = 3.0V, Iout = 16A
VOUT = 2.5 VDC
14.7
ADC
Vin = 3.0V, Iout = 16A
VOUT = 2.0 VDC
11.9
ADC
Vin = 3.0V, Iout = 16A
VOUT = 1.8 VDC
10.8
ADC
Vin = 3.0V, Iout = 16A
VOUT = 1.5 VDC
9.5
ADC
Vin = 3.0V, Iout = 16A
VOUT = 1.2 VDC
7.8
ADC
Vin = 3.0V, Iout = 16A
VOUT = 1.0 VDC
6.5
ADC
Vin = 3.0V, Iout = 16A
VOUT = 0.7525 VDC
5.1
ADC
Input Stand-by Current (Converter disabled)
Vin = 5.0 VDC
Input No Load Current (Converter enabled)
Vin = 5.5 VDC
Input Reflected-Ripple Current - is
10
mA
VOUT = 3.3 VDC
90
mA
VOUT = 2.5 VDC
85
mA
VOUT = 2.0 VDC
80
mA
VOUT = 1.8 VDC
75
mA
VOUT = 1.5 VDC
70
mA
VOUT = 1.2 VDC
65
mA
VOUT = 1.0 VDC
60
mA
VOUT = 0.7525 VDC
50
mA
See Fig. G for setup. (BW = 20 MHz)
15
mAP-P
tech.support@psbel.com
3
YNV05T16 DC-DC Converter
OUTPUT CHARACTERISTICS
Output Voltage Set Point (no load)
Output Regulation4
Output Voltage Tolerance
-1.5
Vout
+1.5
%Vout
Over Line - Full resistive load
0.2
%Vout
Over Load - From no load to full load
0.5
%Vout
(Overall operating input voltage, resistive
load and temperature conditions until end
of life )
-3
+3
%Vout
Output Ripple and Noise - 20MHz bandwidth (Fig. G)
Over line, load and temperature
Vout = 3.3V Full load, Peak-to-Peak
30
60
mVP-P
Vout = 0.7525V Full load, Peak-to-Peak
15
30
mVP-P
External Load Capacitance
Plus full load (resistive)
Min ESR > 1mΩ
1000
μF
5000
μF
16
A
28
A
Min ESR > 10 mΩ
Output Current Range
0
Output Current Limit Inception (IOUT)
Output Short- Circuit Current (Hiccup mode)
20
Short=10 mΩ, continuous
6
Arms
1605
mV
40
µs
DYNAMIC RESPONSE
Load current change from 8A – 16A, di/dt = 5 A/μS
Co = 100 μF ceramic + 1 μF ceramic
Settling Time (VOUT < 10% peak deviation)
Unloading current change 16A – 8A, di/dt = -5 A/μS
Co = 100 μF ceramic + 1 μF ceramic
Settling Time (VOUT < 10% peak deviation)
EFFICIENCY
160
5
mV
40
µs
VOUT = 3.3 VDC
93.5
%
VOUT = 2.5 VDC
92.0
%
VOUT = 2.0 VDC
90.5
%
VOUT = 1.8 VDC
89.5
%
VOUT = 1.5 VDC
88.0
%
VOUT = 1.2 VDC
85.5
%
VOUT = 1.0 VDC
83.5
%
VOUT = 0.7525 VDC
79.5
%
Full load (16A)
Notes:
1
2
3
4
5
The output voltage should not exceed 3.63V (taking into account both the programming and remote sense
compensation).
Note that start-up time is the sum of turn-on delay time and rise time.
The converter is on if ON/OFF pin is left open.
Trim resistor connected across the GND (pin 5) and TRIM pins of the converter.
See waveforms for dynamic response and settling time for different output voltages.
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
4
YNV05T16 DC-DC Converter
Input and Output Impedance
160
Input Voltage Ripple [mV] .
Input Voltage Ripple [mV] .
The YNV05T16 converter should be connected via a low impedance to the DC power source. In many applications,
the inductance associated with the distribution from the power source to the input of the converter can affect the
stability of the converter. It is recommended to use decoupling capacitors in order to ensure stability of the converter
and reduce input ripple voltage. Internally, the converter has 52 µF (low ESR ceramics) of input capacitance.
In a typical application, low - ESR tantalum or POS capacitors will be sufficient to provide adequate ripple voltage
filtering at the input of the converter. However, very low ESR ceramic capacitors of 47 μF to 100 μF are
recommended at the input of the converter in order to minimize the input ripple voltage. They should be placed as
close as possible to the input pins of the converter.
The YNV05T16 has been designed for stable operation with or without external output capacitance. Low ESR ceramic
capacitors (minimum 47μF) placed as close as possible to the load are recommended for improved transient
performance and lower output voltage ripple.
It is important to keep low resistance and low inductance PCB traces when the connecting load to the output pins of
the converter in order to maintain good load regulation.
140
120
100
80
60
40
Vin=5.0V
20
Vin=3.3V
180
160
140
120
100
80
60
40
Vin=5.0V
20
Vin=3.3V
0
0
0
1
2
3
0
4
1
2
3
4
Vout [V]
Vout [V]
Fig. A: Input Voltage Ripple, CIN = 4 x 47 μF ceramic.
Fig. B: Input Voltage Ripple, CIN = 470 μF polymer + 2 x 47
μF ceramic.
Fig. A shows input voltage ripple for various output voltages using four 47μF input ceramic capacitors. The same plot
is shown in Fig. B with one 470 μF polymer capacitor (6TPB470M from Sanyo) in parallel with two 47 μF ceramic
capacitors at full load.
ON/OFF (Pin 10)
The ON/OFF pin is used to turn the converter on or off remotely via a system signal. There are two remote control
options available, positive logic (standard option) and negative logic, and both are referenced to GND. Typical
connections are shown in Fig. C.
7,8
TM
Vin
Nex -v Series
Converter
R*
3
SENSE
1,2,4
10
ON/OFF
Vout
Vin
TRIM
9
Rload
6
5
GND
GND
CONTROL
INPUT
R* is for negative logic option only
Fig. C: Circuit configuration for ON/OFF function.
The positive logic version turns the converter on when the ON/OFF pin is at a logic high or left open, and turns converter
off when at a logic low or shorted to GND.
tech.support@psbel.com
5
YNV05T16 DC-DC Converter
The negative logic version turns the converter on when the ON/OFF pin is at a logic low or left open, and turns the
converter off when the ON/OFF pin is at a logic high or connected to Vin.
The ON/OFF pin is internally pulled-up to Vin for a positive logic version, and pulled-down for a negative logic version.
A TTL or CMOS logic gate, open collector (open drain) transistor can be used to drive ON/OFF pin. When using an open
collector (open drain) transistor with a negative logic option, add a pull-up resistor (R*) of 10kΩ to Vin as shown in Fig.
C. The external pull-up resistor (R*) can be increased to 20kΩ if minimum input voltage is more than 4.5V. This device
must be capable of:
sinking up to 0.6 mA at a low level voltage of 0.8 V
sourcing up to 0.25 mA at a high logic level of 2.3V – 5.5V
Remote Sense (Pin 3)
The remote sense feature of the converter compensates for voltage drops occurring only between Vout of the converter
and the load. The SENSE (Pin 3) pin should be connected at the load or at the point where regulation is required (see
Fig. D). There is no sense feature on the output GND return pin, where a solid ground plane is recommended to provide
a low voltage drop.
If remote sensing is not required, the SENSE pin must be connected to the Vout to ensure the converter will regulate at
the specified output voltage. If these connections are not made, the converter will deliver an output voltage that is
slightly higher than the specified value.
7,8
TM
Vin
Nex -v Series
Converter
3
SENSE
1,2,4
Rw
Vout
10
ON/OFF
Vin
9
TRIM
6
Rload
5
GND
GND
Rw
Fig. D: Remote sense circuit configuration.
Because the sense lead carries minimal current, large trace on the end-user board is not required. However, the sense
trace should be located close to a ground plane to minimize system noise and ensure optimum performance.
When utilizing the remote sense feature, care must be taken not to exceed the maximum allowable output power
capability of the converter, equal to the product of the nominal output voltage and the allowable output current for the
given conditions.
When using remote sense, the output voltage of the converter can be increased up to 0.5V above the sense point
voltage in order to maintain the required voltage across the load. Therefore, the designer must, if necessary, decrease
the maximum current (originally obtained from the derating curves) by the same percentage to ensure the converter’s
actual output power remains at or below the maximum allowable output power.
Output Voltage Programming (Pin 9)
The output voltage can be programmed from 0.7525 V to 3.63 V by connecting an external resistor between the TRIM
pin (Pin 9) and the GND pin (Pin 5); see Fig. E. Note that when a trim resistor is not connected, the output voltage of
the converter is 0.7525 V.
A trim resistor, RTRIM, for a desired output voltage can be calculated using the following equation:
RTRIM =
21.07
− 5.11
(VO -REQ - 0.7525)
[k]
where,
RTRIM = Required value of trim resistor [k]
VO−REQ = Desired (trimmed) output voltage [V]
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
6
YNV05T16 DC-DC Converter
7,8
TM
Nex -v Series
Converter
Vin
3
SENSE
1,2,4
Vout
10
ON/OFF
Vin
TRIM
6
9
GND 5
GND
RTRIM
Rload
Fig. E: Configuration for programming output voltage.
Note that the tolerance of a trim resistor directly affects the output voltage tolerance. It is recommended to use standard
1% or 0.5% resistors. For tighter tolerance, two resistors in parallel are recommended rather than one standard value
from Table 1.
The ground pin of the trim resistor should be connected directly to the converter GND pin (Pin 5) with no voltage drop
in between. Table 1 provides the trim resistor values for popular output voltages.
V0-REG [V]
RTRIM [kΩ]
0.7525
1.0
1.2
1.5
1.8
2.0
2.5
3.3
3.63
open
80.0
41.97
23.1
15
11.78
6.95
3.16
2.21
The Closest Standard
Value [kΩ]
80.6
42.2
23.2
15
11.8
6.98
3.16
2.21
Table 1: Trim Resistor Value
The output voltage can also be programmed by external voltage source. To make trimming less sensitive, a series
external resistor (Rext) is recommended between the Trim pin (pin 9) and the programming voltage source. Control
Voltage can be calculated by the formula:
VCTRL = 0.7 −
(5.11 + REXT )(VO-REQ - 0.7525)
30.1
[V]
Where,
VCTRL = Control voltage [V]
REXT = External resistor between TRIM pin and voltage source; the value can be chosen depending on the required
output voltage range [k]
Control voltages with REXT = 0 and REXT = 15kΩ are shown in Table 2.
V0-REG [V]
0.7525
1.0
1.2
1.5
1.8
2.0
2.5
3.3
3.63
REXT = 0
0.700
0.658
0.624
0.573
0.522
0.488
0.403
0.268
0.257
REXT = 15 kΩ
0.700
0.535
0.401
0.201
-0.000
-0.133
-0.468
-1.002
-1.044
Table 2: Control Voltage [VDC]
tech.support@psbel.com
7
YNV05T16 DC-DC Converter
Input Undervoltage Lockout
Input undervoltage lockout is standard with this converter. The converter will shut down when the input voltage drops
below a pre-determined voltage; it will start automatically when Vin returns to a specified range.
The input voltage must be typically 2.05V for the converter to turn on. Once the converter has been turned on, it will
shut off when the input voltage drops below typically 1.9V.
Output Overcurrent Protection (OCP)
The converter is protected against overcurrent and short-circuit conditions. Upon sensing an over-current condition,
the converter will enter hiccup mode. Once the overload or short-circuit condition is removed, Vout will return to nominal
value.
Overtemperature Protection (OTP)
The converter will shut down under an overtemperature condition to protect itself from overheating caused by operation
outside the thermal derating curves, or operation in abnormal conditions such as system fan failure. After the converter
has cooled to a safe operating temperature, it will automatically restart.
Safety Requirements
Approved to the latest edition and amendment of ITE Safety standards, UL/CSA 62368-1 and EN/IEC 62368-1.
The maximum DC voltage between any two pins is Vin under all operating conditions. Therefore, the unit has ELV (extra
low voltage) output; it meets ES1 requirements under the condition that all input voltages are ELV.
The converter is not internally fused. To comply with safety agencies requirements, a recognized fuse with a maximum
rating of 25 Amps must be used in series with the input line.
General Information
The converter has been characterized for many operational aspects, to include thermal derating (maximum load current
as a function of ambient temperature and airflow) for vertical mounting, efficiency, start-up parameters, output ripple
and noise, and transient response to load step-change.
The figures are numbered as Fig. x.y, where x indicates the different output voltages, and y associates with specific
plots (y = 1 for the vertical thermal derating, …). For example, Fig. x.1 will refer to the vertical thermal derating for all
the output voltages in general.
The following pages contain specific plots or waveforms associated with the converter. Additional comments for
specific data are provided below.
Test Conditions
All thermal and efficiency data presented were taken with the converter soldered to a test board, specifically a 0.060”
thick printed wiring board (PWB) with four layers. The top and bottom layers were not metalized. The two inner layers,
comprising two-ounce copper, were used to provide traces for connectivity to the converter.
The lack of metalization on the outer layers as well as the limited thermal connection ensured that heat transfer from
the converter to the PWB was minimized. This provides a worst-case but consistent scenario for thermal derating
purposes.
All measurements requiring airflow were made in vertical and horizontal wind tunnel facilities using Infrared (IR)
thermography and thermocouples for thermometry.
Ensuring components on the converter do not exceed their ratings is important to maintaining high reliability. If one
anticipates operating the converter at or close to the maximum loads specified in the derating curves, it is prudent to
check actual operating temperatures in the application. Thermographic imaging is preferable; if this capability is not
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
8
YNV05T16 DC-DC Converter
available, then thermocouples may be used. Bel Power Solutions recommends the use of AWG #40 gauge
thermocouples to ensure measurement accuracy. Careful routing of the thermocouple leads will further minimize
measurement error. Refer to Fig. F for optimum measuring thermocouple location.
Fig. F: Location of the thermocouple for thermal testing.
Thermal Derating
Load current vs. ambient temperature and airflow rates are given in Fig. x.1 for maximum temperature of 120 °C.
Ambient temperature was varied between 25 °C and 85 °C, with airflow rates from 30 to 500 LFM (0.15 m/s to 2.5
m/s), and vertical converter mounting. The airflow during the testing is parallel to the long axis of the converter, going
from ON/OFF pin to output pins.
For each set of conditions, the maximum load current was defined as the lowest of:
i.
ii.
The output current at which any MOSFET temperature does not exceed a maximum specified temperature
(120 °C) as indicated by the thermographic image, or
The maximum current rating of the converter (16 A)
During normal operation, derating curves with maximum FET temperature less than or equal to 120 °C should not be
exceeded. Temperature on the PCB at the thermocouple location shown in Fig. F should not exceed 120 °C in order
to operate inside the derating curves.
Efficiency
Fig. x.2 show the efficiency vs. load current plot for ambient temperature of 25 ºC, airflow rate of 200 LFM (1 m/s) and
input voltages of 4.5 V, 5.0 V, and 5.5 V.
Fig. x.3 show the efficiency vs. load current plot for ambient temperature of 25 ºC, airflow rate of 200 LFM (1 m/s) and
input voltages of 3.0 V, 3.3 V, and 3.6 V for output voltages 2.5V.
Power Dissipation
Fig. 3.3V.3 shows the power dissipation vs. load current plot for Ta = 25 ºC, airflow rate of 200 LFM (1 m/s) with
vertical mounting and input voltages of 4.5 V, 5.0 V, and 5.5 V for 3.3 V output voltage.
Start-up
Output voltage waveforms, during the turn-on transient with application of Vin at full rated load current (resistive load)
are shown with 47F external load capacitance at Vin = 5 V in Fig. x.4.
Ripple and Noise
The output voltage ripple waveform is measured at full rated load current. Note that all output voltage waveforms are
measured across a 1F ceramic capacitor. The output voltage ripple and input reflected ripple current waveforms are
obtained using the test setup shown in Fig. G.
iS
1 H
source
inductance
Vsource
TM
Nex -v Series
CIN
4x47F
ceramic
capacitor
DC/DC
Converter
1F
ceramic
capacitor
CO
100F
ceramic
capacitor
Vout
Fig. G: Test setup for measuring input reflected ripple current is and output voltage ripple
tech.support@psbel.com
9
YNV05T16 DC-DC Converter
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
Fig. 3.3V.1: Available load current vs. ambient temperature and airflow rates for Vout = 3.3 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
1.000
4.0
0.975
Power Dissipation [W]
3.2
Efficiency
0.950
0.925
0.900
5.5 V
5.0 V
4.5 V
0.875
2.4
1.6
5.5 V
5.0 V
4.5 V
0.8
0.850
0.0
0
3
6
9
12
15
18
0
3
Load Current [Adc]
6
9
12
15
18
Load Current [Adc]
Fig. 3.3V.2: Efficiency vs. load current and input voltage for
Vout = 3.3 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 3.3V.3: Power loss vs. load current and input voltage for
Vout = 3.3 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 3.3V.4: Turn-on transient for Vout = 3.3 V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage (1 V/div.); Time scale: 2 ms/div.
Fig. 3.3V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout = 3.3
V. Time scale: 2 μs/div.
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
10
YNV05T16 DC-DC Converter
Fig. 3.3V.6: Output voltage response for Vout = 3.3 V to
positive load current step change from 8 A to 16 A with slew
rate of 5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current
(5 A/div.). Co = 100 μF ceramic + 1 μF ceramic. Time scale:
20 μs/div.
Fig. 3.3V.7: Output voltage response for Vout = 3.3 V to
negative load current step change from 16 A to 8 A with slew
rate of -5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF cera-mic. Time scale: 20 μs/div.
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
1.00
1.00
0.95
0.95
0.90
0.90
Efficiency
Efficiency
Fig. 2.5V.1: Available load current vs. ambient temperature and airflow rates for Vout = 2.5 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
0.85
5.5 V
5.0 V
4.5 V
0.80
0.85
3.6 V
3.3 V
3.0 V
0.80
0.75
0.75
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 2.5V.2: Efficiency vs. load current and input voltage for
Vout = 2.5 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 2.5V.3: Efficiency vs. load current and input voltage for
Vout = 2.5 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
tech.support@psbel.com
11
YNV05T16 DC-DC Converter
Fig. 2.5V.4: Turn-on transient for Vout = 2.5 V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage (1 V/div.); Time scale: 2 ms/div.
Fig. 2.5V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout = 2.5
V. Time scale: 2 μs/div.
Fig. 2.5V.6: Output voltage response for Vout = 2.5 V to
positive load current step change from 8 A to 16 A with slew
rate of 5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current
(5 A/div.). Co = 100 μF ceramic + 1 μF ceramic. Time scale:
20 μs/div.
Fig. 2.5V.7: Output voltage response for Vout = 2.5 V to
negative load current step change from 16 A to 8 A with slew
rate of -5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
Fig. 2.0V.1: Available load current vs. ambient temperature and airflow rates for Vout = 2.0 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
YNV05T16 DC-DC Converter
1.00
1.00
0.95
0.95
0.90
0.90
Efficiency
Efficiency
12
0.85
5.5 V
5.0 V
4.5 V
0.80
0.85
3.6 V
3.3 V
3.0 V
0.80
0.75
0.75
0
3
6
9
12
15
18
Load Current [Adc]
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 2.0V.2: Efficiency vs. load current and input voltage for
Vout = 2.0 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 2.0V.3: Efficiency vs. load current and input voltage for
Vout = 2.0 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 2.0V.4: Turn-on transient for Vout = 2.0 V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage (1 V/div.); Time scale: 2 ms/div.
Fig. 2.0V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout = 2.0
V. Time scale: 2 μs/div.
Fig. 2.0V.6: Output voltage response for Vout = 2.0 V to
positive load current step change from 8 A to 16 A with slew
rate of 5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
Fig. 2.0V.7: Output voltage response for Vout = 2.0 V to
negative load current step change from 16 A to 8 A with slew
rate of -5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
tech.support@psbel.com
13
YNV05T16 DC-DC Converter
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
1.00
1.00
0.95
0.95
0.90
0.90
Efficiency
Efficiency
Fig. 1.8V.1: Available load current vs. ambient temperature and airflow rates for Vout = 1.8 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
0.85
5.5 V
5.0 V
4.5 V
0.80
0.85
3.6 V
3.3 V
3.0 V
0.80
0.75
0.75
0
3
6
9
12
15
18
0
3
Load Current [Adc]
6
9
12
15
18
Load Current [Adc]
Fig. 1.8V.2: Efficiency vs. load current and input voltage for
Vout = 1.8 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 1.8V.3: Efficiency vs. load current and input voltage for
Vout = 1.8 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 1.8V.4: Turn-on transient for Vout = 1.8 V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage
(1 V/div.); Time scale: 2 ms/div.
Fig. 1.8V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout = 1.8
V. Time scale: 2 μs/div.
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
14
YNV05T16 DC-DC Converter
Fig. 1.8V.6: Output voltage response for Vout = 1.8 V to
positive load current step change from 8 A to 16 A with slew
rate of 5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
Fig. 1.8V.7: Output voltage response for Vout = 1.8 V to
negative load current step change from 16 A to 8 A with slew
rate of -5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
1.00
1.00
0.95
0.95
0.90
0.90
Efficiency
Efficiency
Fig. 1.5V.1: Available load current vs. ambient temperature and airflow rates for Vout = 1.5 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
0.85
5.5 V
5.0 V
4.5 V
0.80
0.85
3.6 V
3.3 V
3.0 V
0.80
0.75
0.75
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 1.5V.2: Efficiency vs. load current and input voltage for
Vout = 1.5 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 1.5V.3: Efficiency vs. load current and input voltage for
Vout = 1.5 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
tech.support@psbel.com
15
YNV05T16 DC-DC Converter
Fig. 1.5V.4: Turn-on transient for Vout = 1.5 V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage
(1 V/div.); Time scale: 2 ms/div.
Fig. 1.5V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout = 1.5
V. Time scale: 2 μs/div.
Fig. 1.5V.6: Output voltage response for Vout = 1.5 V to
positive load current step change from 8 A to 16 A with slew
rate of 5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
Fig. 1.5V.7: Output voltage response for Vout = 1.5 V to
negative load current step change from 16 A to 8 A with slew
rate of -5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
Fig. 1.2V.1: Available load current vs. ambient temperature and airflow rates for Vout = 1.2 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
YNV05T16 DC-DC Converter
0.95
0.95
0.90
0.90
Efficiency
Efficiency
16
0.85
0.80
5.5 V
5.0 V
4.5 V
0.75
0.85
0.80
3.6 V
3.3 V
3.0 V
0.75
0.70
0.70
0
3
6
9
12
15
18
Load Current [Adc]
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 1.2V.2: Efficiency vs. load current and input voltage for
Vout = 1.2 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 1.2V.3: Efficiency vs. load current and input voltage for
Vout = 1.2 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 1.2V.4: Turn-on transient for Vout = 1.2 V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage (1 V/div.); Time scale: 2 ms/div.
Fig. 1.2V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout = 1.2
V. Time scale: 2 μs/div.
Fig. 1.2V.6: Output voltage response for Vout = 1.2 V to
positive load current step change from 8 A to 16 A with slew
rate of 5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
Fig. 1.2V.7: Output voltage response for Vout = 1.2 V to
negative load current step change from 16 A to 8 A with slew
rate of -5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
tech.support@psbel.com
17
YNV05T16 DC-DC Converter
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
0.95
0.95
0.90
0.90
0.85
0.85
Efficiency
Efficiency
Fig. 1.0V.1: Available load current vs. ambient temperature and airflow rates for Vout = 1.0 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
0.80
5.5 V
5.0 V
4.5 V
0.75
0.80
3.6 V
3.3 V
3.0 V
0.75
0.70
0.70
0
3
6
9
12
15
18
0
3
Load Current [Adc]
6
9
12
15
18
Load Current [Adc]
Fig. 1.0V.2: Efficiency vs. load current and input voltage for
Vout = 1.0 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 1.0V.3: Power loss vs. load current and input voltage for
Vout = 1.0 V converter mounted vertically with air flowing
from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and Ta = 25
C.
Fig. 1.0V.4: Turn-on transient for Vout = 1.0 V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage (0.5 V/div.); Time scale: 2
ms/div.
Fig. 1.0V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout = 1.0
V. Time scale: 2 μs/div.
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
18
YNV05T16 DC-DC Converter
Fig. 1.0V.6: Output voltage response for Vout = 1.0 V to
positive load current step change from 8 A to 16 A with slew
rate of 5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
Fig. 1.0V.7: Output voltage response for Vout = 1.0 V to
negative load current step change from 16 A to 8 A with slew
rate of -5 A/μs at Vin = 5 V. Top trace: output voltage (100
mV/div.); Bottom trace: load current (5 A/div.). Co = 100 μF
ceramic + 1 μF ceramic. Time scale: 20 μs/div.
20
Load Current [Adc]
16
12
500 LFM (2.5 m/s)
400 LFM (2.0 m/s)
300 LFM (1.5 m/s)
200 LFM (1.0 m/s)
100 LFM (0.5 m/s)
30 LFM (0.15 m/s)
8
4
0
20
30
40
50
60
70
80
90
Ambient Temperature [°C]
0.90
0.90
0.85
0.85
Efficiency
Efficiency
Fig. 0.7525V.1: Available load current vs. ambient temperature and airflow rates for Vout = 1.0 V converter mounted vertically with
Vin = 5 V, air flowing from pin 10 to pin 1, and maximum MOSFET temperature 120 C.
0.80
0.75
5.5 V
5.0 V
4.5 V
0.70
0.80
0.75
3.6 V
3.3 V
3.0 V
0.70
0.65
0.65
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 0.7525V.2: Efficiency vs. load current and input voltage
for Vout = 0.7525 V converter mounted vertically with air
flowing from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and
Ta = 25 C.
0
3
6
9
12
15
18
Load Current [Adc]
Fig. 0.7525V.3: Efficiency vs. load current and input voltage
for Vout = 0.7525 V converter mounted vertically with air
flowing from pin 10 to pin 1 at a rate of 200 LFM (1 m/s) and
Ta = 25 C.
tech.support@psbel.com
19
YNV05T16 DC-DC Converter
Fig. 0.7525V.4: Turn-on transient for Vout = 0.7525V with
application of Vin at full rated load current (resistive) and 100
μF external capacitance at Vin = 5 V. Top trace: Vin (5 V/div.);
Bottom trace: output voltage (1 V/div.); Time scale: 2 ms/div.
Fig. 0.7525V.5: Output voltage ripple (20 mV/div.) at full rated
load current into a resistive load with external capacitance
100 μF ceramic + 1 μF ceramic and Vin = 5 V for Vout =
0.7525 V. Time scale: 2 μs/div.
Fig. 0.7525V.6: Output voltage response for Vout = 0.7525 V
to positive load current step change from 8 A to 16 A with
slew rate of 5 A/μs at Vin = 5 V. Top trace: output voltage
(100 mV/div.); Bottom trace: load current (5 A/div.). Co = 100
μF ceramic + 1 μF ceramic. Time scale: 20 μs/div.
Fig. 0.7525V.7: Output voltage response for Vout = 0.7525 V
to negative load current step change from 16 A to 8 A with
slew rate of -5 A/μs at Vin = 5 V. Top trace: output voltage
(100 mV/div.); Bottom trace: load current (5 A/div.). Co = 100
μF ceramic + 1 μF ceramic. Time scale: 20 μs/div.
Europe, Middle East
+353 61 225 977
North America
+1 408 785 5200
© 2020 Bel Power Solutions & Protection
BCD.00675_B1
Asia-Pacific
+86 755 298 85888
20
YNV05T16 DC-DC Converter
PAD/PIN CONNECTIONS
Pad/Pin #
Function
1
Vout
2
Vout
3
Vout SENSE
4
Vout
5
GND
6
GND
7
Vin
8
Vin
9
TRIM
10
ON/OFF
YNV05T16 Pinout (Through-Hole - SIP)
YNV05T16 Platform Notes
•
•
All dimensions are in inches [mm]
Connector Material: Phosphor Bronze/
Brass Alloy 360
Connector Finish: Gold over Nickel
Converter Weight: 0.26 oz [7.28 g]
Converter Height: 0.585” Max.
Recommended Through Hole Via/Pad:
Min. 0.043” X 0.064” [1.09 x 1.63 mm]
•
•
•
•
Product
Series
YNV
Y-Series
Input
Voltage
05
3.0 – 5.5 V
Mounting
Scheme
T
T Through-Hole
(SIP)
Rated Load
Current
16
16 A
(0.7525 V to 3.63 V)
Enable Logic
–
Environmental
0
0 Standard
(Positive Logic)
D Opposite of Standard
(Negative Logic)
No Suffix RoHS leadsolder-exempt compliant
G
RoHS compliant
for all six substances
The example above describes P/N YNV05T16-0: 3.0V – 5.5V input, thru-hole (SIP), 16A at 0.7525V to 3.63V output, standard
enable logic, and RoHS lead solder exemption compliant. Please consult factory regarding availability of a specific version.
NUCLEAR AND MEDICAL APPLICATIONS - Products are not designed or intended for use as critical components in life support
systems, equipment used in hazardous environments, or nuclear control systems.
TECHNICAL REVISIONS - The appearance of products, including safety agency certifications pictured on labels, may change
depending on the date manufactured. Specifications are subject to change without notice.
tech.support@psbel.com