AG9905MT [SILVERTEL]
Ultra Miniature PoE Module;型号: | AG9905MT |
厂家: | Silvertel |
描述: | Ultra Miniature PoE Module |
文件: | 总21页 (文件大小:1054K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
V2.4 April 2020
Datasheet
Ag9900
Ultra Miniature PoE Module
Features
IEEE802.3af compliant
1500V isolated DC/DC Converter
Ultra Low Profile
Tiny SMT (14mm x 21mm X 13mm) or
DIL package (14mm x 21mm X 8mm)
Low cost
Input voltage range 36V to 57V
Minimal external components
required
Short-circuit protection
Industrial temperature option
available
Over temperature protection
(Industrial Temperature version- MT or LP)
Adjustable Output
Silvertel “design-in” assistance
Description
The Ag9900 Power-over-Ethernet (PoE) modules are the smallest POE solution in the
world and designed to extract power from a conventional twisted pair Category 5
Ethernet cable, conforming to the IEEE 802.3af PoE standard.
The Ag9900 signature and control circuit provides the PoE compatibility signature
required by the Power Sourcing Equipment (PSE) before applying up to 15W power to
the port. The Ag9900 provides a Class 0 signature.
The DC/DC converter operates over a wide input voltage range and provides a
regulated output. The DC/DC converter also has built-in short-circuit output protection.
© Silver Telecom 2020
V2.4 April 2020
Datasheet
Ag9900
Ultra Miniature PoE Module
Table of Contents
1
Product Overview ................................................................................................................................... 3
1.1
1.2
1.3
Ag9900 Product Selector ................................................................................................................. 3
Package Format............................................................................................................................... 4
Pin Description ................................................................................................................................. 5
2
Functional Description ........................................................................................................................... 6
2.1
2.2
Typical Connections......................................................................................................................... 6
Input.................................................................................................................................................. 7
PD Signature............................................................................................................................ 7
Power Classification................................................................................................................. 7
Start-up Power ......................................................................................................................... 7
Output............................................................................................................................................... 8
Output Adjustment ................................................................................................................... 8
Additional Output Filtering........................................................................................................ 9
2.2.1
2.2.2
2.2.3
2.3
2.3.1
2.3.2
3
4
Protection .............................................................................................................................................. 10
3.1
3.2
Input Protection .............................................................................................................................. 10
Thermal Protection......................................................................................................................... 10
Operating Temperature Range ............................................................................................................ 11
4.1
Thermal Considerations ................................................................................................................. 13
Typical Application ............................................................................................................................... 15
Isolation ................................................................................................................................................. 16
5
6
6.1
Layout Consideration ..................................................................................................................... 16
EMC ........................................................................................................................................................ 17
Electrical Characteristics..................................................................................................................... 18
7
8
8.1
8.2
8.3
Absolute Maximum Ratings1 .......................................................................................................... 18
Recommended Operating Conditions............................................................................................ 18
DC Electrical Characteristics.......................................................................................................... 18
9
Package.................................................................................................................................................. 20
9.1
9.2
Ag9900M/MT.................................................................................................................................. 20
Ag9900LP....................................................................................................................................... 21
Table of Figures
Figure 1: Block Diagram .................................................................................................................................... 4
Figure 2: Ag9900 Package Format.................................................................................................................... 4
Figure 6: Typical Connection Diagram .............................................................................................................. 6
Figure 3: Typical System Diagram .................................................................................................................... 7
Figure 4: Output Adjustment.............................................................................................................................. 8
Figure 5: Output Filtering................................................................................................................................... 9
Figure 7: Ag9900 Input Protection................................................................................................................... 10
Figure 8: Ag9924M Operating Profile.............................................................................................................. 11
Figure 9: Ag9912M Operating Profile.............................................................................................................. 12
Figure 10: Ag9905M Operating Profile............................................................................................................ 12
Figure 11: Ag9903M Operating Profile............................................................................................................ 12
Figure 12: Ag9912LP Operating Profile........................................................................................................... 12
Figure 13: Ag9905LP Operating Profile........................................................................................................... 12
Figure 14: Ag9903LP Operating Profile........................................................................................................... 12
Figure 15: Ag9900M Thermal Relief................................................................................................................ 13
Figure 16: Thermal Gap Pad Position ............................................................................................................. 14
Figure 17: Typical Application ......................................................................................................................... 15
Figure 18: Layout Consideration ..................................................................................................................... 16
Figure 19: EMC Filtering.................................................................................................................................. 17
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V2.4 April 2020
Datasheet
Ag9900
Ultra Miniature PoE Module
1 Product Overview
Ag9900 Product Selector
Standard
Date code3 and
Voltage Marking
Part Number1
Nominal Output Voltage
Output Power2
Ag9903M
Ag9905M
Ag9912M
Ag9924M
3.3V
5.0V
6 Watts
9 Watts
3 WWYY
5 WWYY
12.0V
24.0V
12 Watts
12 Watts
12 WWYY
24 WWYY
Industrial Temperature
Date code3 and
Voltage Marking
Part Number1
Nominal Output Voltage
Output Power2
Ag9903MT
Ag9905MT
Ag9912MT
Ag9924MT
3.3V
5.0V
6 Watts
9 Watts
3T WWYY
5T WWYY
12T WWYY
24T WWYY
12.0V
24.0V
12 Watts
12 Watts
Low Profile
Date code3 and
Voltage Marking
Output Power
Part Number1
Nominal Output Voltage
70˚C
85˚C
Ag9903LP
Ag9905LP
Ag9912LP
3.3V
5.0V
4.9 Watts
7 Watts
3.6 Watts
4.5 Watts
6 Watts
3 WWYY
5 WWYY
12 WWYY
12.0V
10 Watts
Note 1: The Ag9900 complies with the European Directive 2011/65/EU for the Restriction of use of certain Hazardous Substances
(RoHS) including Directive 2015/863 published in 2015, amending Annex II of Directive 2011/65/EU. Moisture Sensitive
Level 1 and HBM 1.
Note 2: At 25°C with VIN = 48V
Note 3: Date code format: “WW” = Week Number, “YY” = Year; if the industrial temperature version, Ag9900MT, is chosen it will be
marked with the letter “T” after the voltage variant.
Table 1: Ordering Information
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Datasheet
Ag9900
Ultra Miniature PoE Module
VA1
ADJ
Ag9900
~
~
~
+VDC
+VDC
Input
+
+
VIN+
-
-
VA2
~
~
VB1
+
Signature
& Control
C1
C2
DC
Output
DC:DC
Converter
~
Input
10uF
100uF
~
VB2
~
VIN-
-VDC
-VDC
Figure 1: Block Diagram
Package Format
Ag9900M
Ag9900LP
1
1
(Top View)
(Top View)
1 2
3 4
1 2
3 4
8 7
6 5
(Bottom View)
(Bottom View)
8 7
6 5
Figure 2: Ag9900 Package Format
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Datasheet
Ag9900
Ultra Miniature PoE Module
Pin Description
Pin #
Name
Description
1
2
+VDC
-VDC
ADJ
DC Output This pin provides the regulated output from the DC/DC converter.
DC Return This pin is the return path for the +VDC output.
3
4
Output Adjust The output voltage can be adjusted from its nominal value, by
connecting an external resistor from this pin to either the +VDC pin or the -
VDC pin.
5
6
7
8
Direct Input + This pin connects to the positive (+) output of the input bridge
rectifiers.
VIN+
VIN-
Direct Input - This pin connects to the negative (-) output of the input bridge
rectifiers.
Table 2: Pin Description
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Datasheet
Ag9900
Ultra Miniature PoE Module
2 Functional Description
Typical Connections
The Ag9900 requires minimal external components as shown in Figure 3.
C1 must be fitted for output stability and should be a minimum of 100µF. This capacitor
should be positioned as close to the output pins as possible. C1 is also required to
handle load step change and reduce the output ripple. For applications where the output
needs to cope with high load step changes, or to reduce the output ripple we
recommend using a low ESR electrolytic as this reduces the output ripple. Also a low
ESR capacitor is essential for operation below 0°C.
BR1 and BR2 can be inexpensive bridge rectifiers, for example MB4S or MB6S.
RJ-45
4
VB1
BR1
5
7
8
1
Ag9900
~
~
ADJ
-
+
VB2
VA1
VIN+
+VDC
BR2
+
~
~
RB
-
+
RX
TX
Output
C1
C2
2
3
VA2
-VDC
VIN-
C1 = 100µF 25V
C2 = 10uF 25V
RB = ≥ I load min
6
Figure 3: Typical Connection Diagram
The output adjust input (ADJ) is optional, it is provided to give greater flexibility to the
Ag9900 product range. Further information on using these inputs can be found in
Section 2.3.1.
The Ag9900 must always supply a minimum current; see Section 8.3 - Minimum Load
for more information. When operated below this level the Ag9900 will emit a low level
audible noise. The reason that the module emits this noise is due to the dc/dc converter
running in discontinuous mode.
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Datasheet
Ag9900
Ultra Miniature PoE Module
If this audible noise is not an issue, then the Ag9900 can work safely with a much
smaller load. But to ensure that the PSE has a sufficient load to meet its Maintain Power
Signature (MPS), it would be advisable not to operate the Ag9900 below the specified
minimum load.
Input
The Ag9900 is compatible with equipment that uses Alternative A (power on data pair)
or Alternative B (power on spare pair) options, see Figure 4. It is specified that the PSE
does not apply power to both outputs at the same time (Refer to IEEE802.3af for more
information).
POWER SOURCING
EQUIPMENT (PSE)
POWERED DEVICE
(PD)
4
5
1
4
5
1
+
+/-
VA1
VB1
~
-
TX
RX
RX
TX
+VDC
VIN+
VIN-
Ag9900
+
2
3
6
2
3
6
~
-
~
+
DC
OUTPUT
PSE
(48V)
-VDC
~
VA2
VB2
+/-
-
7
8
7
8
Figure 4: Typical System Diagram
2.2.1 PD Signature
When the Ag9900 is connected to the Cat5e cable, it will automatically present a
Powered Device (PD) signature to the Power Sourcing Equipment (PSE) or Midspan
Equipment, when requested. The equipment will then recognise that a powered device
is connected to that line and supply power.
2.2.2 Power Classification
The Ag9900 is set to Class 0 (0.44 Watts to 12.95 Watts) operation.
2.2.3 Start-up Power
It is important that during start-up the Ag9900 input voltage is ≥42V, this will ensure that
the module powers up correctly. Once the dc/dc converter is up and running the module
will work normally even if the input voltage is reduced to its minimum level of 36V.
When using an IEEE802.3af compliant PSE this will not be an issue, as the minimum
output voltage of the PSE must be ≥44V.
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Datasheet
Ag9900
Ultra Miniature PoE Module
Output
The Ag9900’s DC/DC converter provides a regulated output that has built-in short-circuit
output protection – refer to Table 1: Ordering Information for voltage and power ratings.
2.3.1 Output Adjustment
The Ag9900 has an ADJ pin, which allows the output voltage to be increased or
decreased from its nominal value. Figure 5 shows how the ADJ pin is connected.
Ag9900
Ag9900
+VDC
+VDC
R
ADJ
ADJ
R
-VDC
-VDC
Reducing the output
voltage from nominal
Increasing the output
voltage from nominal
Figure 5: Output Adjustment
Reducing the output voltage, connect R between ADJ and +VDC
Value of R
Open Circuit
0 Ohms
Ag9903 output
3.30V
Ag9905 output
5.00V
Ag9912 Output
12.00V
Ag9924 Output
24.00V
3.20V
4.48V
10.0V
19.85V
Increasing the output voltage, connect R between ADJ and -VDC
Value of R
Open Circuit
0 Ohms
Ag9903 output
3.30V
Ag9905 output
5.00V
Ag9912 output
12.00V
Ag9924 Output
24.00V
3.78V
5.65V
12.75V
25.10V
Table 3: Output Adjustment Resistor (R) Value
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Datasheet
Ag9900
Ultra Miniature PoE Module
2.3.2 Additional Output Filtering
The Ag9900 as shown in Figure 3 offers the minimum capacitance the customer must
fit, however Figure 6 shows two cost effective methods for reducing the ripple and
noise, if required.
Ag9900
Ag9900
L1
+VDC
+VDC
+
+
Output
Output
C1
C1 C2 C3
C2
C3
-VDC
-VDC
C1 = 100µF 25V
C1 = 100µF 25V
C2 & C3 = 10µF 25V Ceramic
C2 & C3 = 10µF 25V Ceramic
L1 = 1.8µH
Output Filter A
Output Filter B
Figure 6: Output Filtering
The simplest and cheapest solution is shown in Figure 6 - Output Filter A. Taking the
Ag9912M as an example, this will reduce the ripple and noise to typically 120mVp-p at
maximum load. Adding a PI filter, as shown in Figure 6 – Output Filter B, will take the
ripple and noise level down further to typically 25mVp-p.
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Datasheet
Ag9900
Ultra Miniature PoE Module
3 Protection
Input Protection
The Ag9900 must be protected from over-voltages exceeding the 80V maximum rated
surge input voltage. An inexpensive but effective solution can be achieved by
connecting a tranzorb diode across the input; see Figure 7.
Ag9900
~
-
-
+
+
~
~
VIN+
VIN-
SMAJ58A
~
Figure 7: Ag9900 Input Protection
More information is available is Apps Note “ANX-POE-Protection”.
Thermal Protection
The standard Ag9900M does not have built-in thermal protection. If this module is
intended to be used in high ambient temperatures >50°C then we would recommend
either the Industrial temperature version Ag9900MT or the Ag9900LP (both include
thermal protection) to be used.
The thermal protection reduces the output power, see Figure 8 through Figure 14, to
ensure that the maximum component temperature is not exceeded. Full output power
will be restored when the ambient temperature drops back down into the safe operating
range.
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Datasheet
Ag9900
Ultra Miniature PoE Module
4 Operating Temperature Range
Because the Ag9900 is a power component, it will generate heat, so it is important that
this be taken into consideration at the design stage.
The heart of the Ag9900 is a DC/DC converter, which like any other power supply will
generate heat. The amount of heat generated by the module will depend on the load it
is required to drive, and the input voltage supplied by the PSE. The information shown
within this section of datasheet is referenced to a nominal 48Vdc input voltage supplied
by the PSE.
The Ag9900M has a maximum ambient operating temperature of 70˚C without any
heat-sinking, while the Ag9900MT and Ag9900LP able to operate up to 85˚C while
heatsinking to a host PCB; see below Figure 8 through Figure 14. These results were
performed in an environment chamber - Associated Environmental System SD-302.The
performance of the Ag9900M can be improved by forcing the airflow directly over the
part, and by using a thermal pad such as Bergquist .1” Ultra soft gap pad or thermal
paste such as thermally conductive Oxime Cure paste. The customers PCB can then be
thermally mounted (using a Bergquist 0.1” Ultra soft gap pad) to the chassis of the host
equipment by using the thermal relief pads (see Figure 15 and application note “ANX-
POE-Thermal-Considerations” for more information).
The output stage of the Ag9900M has no built-in thermal protection; however thermal
protection is available with the Industrial temperature version Ag9900MT or Ag9900LP
module. To prevent the module from being damaged it is recommended that the module
be powered by an IEEE 802.3af compliant PSE or midspan equipment. However the
Ag9900 may be powered by a user designed power supply which should include
thermal and over current protection and be current limited to 400mA.
12
11
10
9
8
7
6
Ag9924M
5
4
3
2
1
85
-40 -30 -20 -10
0
10 20 30 40 50 60 70
Ambient Temperature (°C)
Figure 8: Ag9924M Operating Profile
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Datasheet
Ag9900
Ultra Miniature PoE Module
10
9
8
7
6
5
4
3
2
1
12
11
10
9
8
7
6
5
4
3
9W
6W
Ag9912LP
Ag9912M
2
1
85
-40 -30 -20 -10
0
10 20 30 40 50 60 70
85
-40 -30 -20 -10
0
10 20 30 40 50 60 70
Ambient Temperature (°C)
Ambient Temperature (°C)
Figure 9: Ag9912M Operating Profile
Figure 10: Ag9912LP Operating Profile
7
6
9
8
7
6
5
4.5W
5
4
3
2
1
6W
Ag9905LP
Ag9905M
4
3
2
1
85
85
-40 -30 -20 -10
0
10 20 30 40 50 60 70
-40 -30 -20 -10
0
10 20 30 40 50 60 70
Ambient Temperature (°C)
Ambient Temperature (°C)
Figure 11: Ag9905M Operating Profile
Figure 12: Ag9905LP Operating Profile
5
6
5
3.6W
4
3
2
1
4.5W
4
3
2
1
Ag9903LP
Ag9903M
85
-40 -30 -20 -10
0
10 20 30 40 50 60 70
85
-40 -30 -20 -10
0
10 20 30 40 50 60 70
Ambient Temperature (°C)
Ambient Temperature (°C)
Figure 13: Ag9903M Operating Profile
Figure 14: Ag9903LP Operating Profile
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Datasheet
Ag9900
Ultra Miniature PoE Module
Thermal Considerations
Each application is different; therefore it is impossible to give fixed and absolute thermal
recommendations. Due to the small size of this module, it is important that as much
heat as possible is drawn away from it. It is also important that any enclosure has
sufficient ventilation for the Ag9900 and a direct airflow if possible.
One simple method for drawing some of the heat away from the Ag9900 is by means of
power planes connected to the +VDC and -VDC pins of the Ag9900. This technique can
be used to draw heat away from the DC/DC converter via the output pins.
These power planes must be on the outer layers of the PCB and the best results are
achieved by having power planes on both sides of the main board with multiple through-
hole connections. An example of this is shown in Figure 15 with an Ag9900M module.
Bottom side
copper pour of
customers ꢀPCB
8
Copper pour with via
holes connecting to
bottom side of customers ꢀ
Heatpad
PCB
Keep out area, ensure the
output tracks have
sufficient clearance from
the module input tracks to
maintain the1500V
isolation barrie.r
1
- VDC
+VDC
Power
Plane
Figure 15: Ag9900M Thermal Relief
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Datasheet
Ag9900
Ultra Miniature PoE Module
A method that we would recommend when using the Ag9900 series is the use of a
thermal gap pad or thermal paste, such as Berquist ultra soft 0.1in or Thermally
conductive Oxime Cure paste, be placed underneath the Ag9900 PCB as shown below
in Figure 16. The gap pad or paste must fully cover the components on the bottom side
of the PCB to provide the best possible thermal conduction through the material to the
customers PCB.
Position of
Gap Pad
Ag9900M
Bottom Side
1
Customers
PCB
Side View
Gap Pad
Or
Thermally Conductive Oxime Cure paste
Figure 16: Thermal Gap Pad Position
It is important to remember that the ESR of the external electrolytic capacitors will
increase considerably when the ambient temperature falls below 0°C. If the Ag9900 is
going to be used in applications where the ambient temperature can fall below 0°C,
selection of appropriate output filter components must be done at the design stage.
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Datasheet
Ag9900
Ultra Miniature PoE Module
5 Typical Application
The Ag9900 can be used in numerous applications. In the example shown in Figure 17,
the data outputs from the switch are connected to the inputs of a midspan. The midspan
will then add power (to the data) on each output that supports Power over Ethernet
(PoE).
In this example port 1 is connected to an Ethernet camera and port 2 is connected to a
wireless access point, both of these devices have a built-in Ag9900. When the midspan
is switched on (or when the device is connected), the midspan will check each output
for a PoE signature. On ports 1 and 2 the Ag9900 will identify themselves as PoE
enabled devices and the midspan will supply both data and power to these peripherals.
The other ports (shown in this example) will not have a PoE signature and the midspan
will only pass the data through to these peripherals. The midspan will continuously
monitor each output to see if a PoE enabled device has been added or removed.
Switch
8
8
1
Patch Cables
1 Midspan Equipment
Ethernet
Camera
Ag9900M
Silvertel
Ag9900M
Wireless
Access Point
PC's and other non
PoE peripherals
Figure 17: Typical Application
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Datasheet
Ag9900
Ultra Miniature PoE Module
6 Isolation
To meet the safety isolation requirements of IEEE802.3af section 33.4.1 a Powered
Device (PD) must pass the electrical strength test of IEC 60950 sub clause 6.2. This
calls for either a) 1500Vac test or b) 1500Vdc impulse test. The Ag9900 is specified to
meet the 1500Vdc impulse test. It is also important that the tracks on either side of the
isolation barrier have at least a 3mm clearance, see Figure 10 & Figure 14 for more
information.
Layout Consideration
Figure 18 shows the position of the isolation barrier, this area must be kept clear of
tracks under the Ag9900 module.
Ag9900 Bottom side
8
Keep out area
14.00 11.38
3.00
6.27
2.54
5.08
11.03
3.00
Note: The keep out area is on the top layer of the mother-board under the module
Figure 18: Layout Consideration
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Datasheet
Ag9900
Ultra Miniature PoE Module
7 EMC
The Ag9900 uses a dc/dc converter with pulse width modulation, so care does need to
be taken to minimise emissions.
The Ag9900 is designed to meet EN55032 Class B (pre-compliance test results are
available from Silvertel) however, because the Ag9900 will only be one component
within your system, it is impossible to say whether the final product will pass EMC
testing without the need for additional filtering. Figure 19 shows our recommended EMC
Filter configuration for the Ag9900. For more information, tips and suggestions refer to
the application note “ANX-POE-EMI” on our website.
RJ-45
C3
4
VB1
BR1
5
7
8
1
Ag9900
~
~
ADJ
-
+
VIN+
L1
L2
L3
VB2
VA1
+VDC
BR2
+
~
~
D1
RB
Output
-
+
RX
TX
C1
C2
2
3
-VDC
VA2
L4
L5
L6
C1 = 10µF 25V
C2 = 100uF 25V
VIN-
C3, C4 = 4.7nF 2KV
D1 = SMAJ58A
RB = ≥ I load min
6
BR1 & BR2 = MB4S
L1 – L6 = MMZ2012S102A
C4
Figure 19: EMC Filtering
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Datasheet
Ag9900
Ultra Miniature PoE Module
8 Electrical Characteristics
Absolute Maximum Ratings1
Parameter
Symbol
Min
Max
Units
1
2
3
DC Supply Voltage
VCC
VSURGE
TS
-0.3
-0.6
-40
60
80
V
V
DC Supply Voltage Surge for 1ms
Storage Temperature
+100
˚C
Note 1: Exceeding the above ratings may cause permanent damage to the product. Functional operation under these conditions is
not implied. Maximum ratings assume free airflow.
Recommended Operating Conditions
Parameter
Symbol
Min
Typ
Max
Units
1
2
Input Supply Voltage1
Under Voltage Lockout
VIN
36
30
48
57
36
70
V
V
VLOCK
Ag9900M
Ag9900MT
Ag9900LP
Operating
3
TOP
-40
25
Ta /˚C
Temperature2
85
Note 1: With minimum load
Note 2: See Section 4: Operating Temperature Range
DC Electrical Characteristics
DC Characteristic
Variant1
Sym
Min
Typ2
Max Units
Ag9924
Ag9912
23.3
11.5
4.75
3.1
24
12
5
24.8
12.5
5.25
3.5
1
2
Nominal Output Voltage
Minimum Load3
+VDC
V
Ag9905
Ag9903
3.3
Ag9924
50
Ag9912
100
ILOAD
mA
Ag9905
200
Ag9903
Ag9924M
Ag9912M4
Ag9912LP
Ag9905M
Ag9905LP
Ag9903M
Ag9903LP
0.5
1.0
0.8
1.8
1.4
1.8
1.5
Output Current
(VIN = 48V)
3
Iout
A
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Datasheet
Ag9900
Ultra Miniature PoE Module
DC Characteristic
Variant1
Sym
Min
Typ2
Max Units
Ag9924M
Ag9912M
Ag9912LP
Ag9905M
Ag9905LP
Ag9903M
Ag9903LP
Ag9924M
Ag9912M
Ag9912LP
Ag9905M
Ag9905LP
Ag9903M
Ag9903LP
Ag9924M
Ag9912M
Ag9912LP
Ag9905M
Ag9905LP
Ag9903M
Ag9903LP
Ag9924M
Ag9912M
Ag9912LP
Ag9905M
Ag9905LP
Ag9903M
Ag9903LP
0.14
0.02
0.02
0.05
0.01
0.05
0.01
0.12
0.1
4
5
6
7
Line Regulation
VLINE
%
0.05
0.12
0.08
0.7
Load Regulation –
Min to Max (VIN = 48V)
VLOAD
%
0.09
125
120
TBD
95
Output Ripple and Noise5@ Max load
VRN
mVp-p
TBD
78
TBD
87
86
83
Peak Efficiency
EFF
%
80
8
9
Short-Circuit Duration6
TSC
∞
sec
VPK
Isolation Voltage (I/O) - Impulse Test
VISO
1500
Note 1: Electrical characteristics are identical for the Ag9900M and Ag9900MT variants.
Note 2: Typical figures are at 25°C with a nominal 48V supply and are for design aid only. Not Guaranteed
Note 3: The module can emit an audible noise, if operated at less than the stated minimum ILOAD and cause the PSE to fail its MPS.
Note 4: The Ag9912 output must not exceed 12W.
Note 5: Measured with external filter A. The output ripple and noise can be reduced further with external filter B, see Section 2.3.2.
Note 6: >200mohm short due to thermal limitation.
© Silver Telecom 2020
19
V2.4 April 2020
Datasheet
Ag9900
Ultra Miniature PoE Module
9 Package
Ag9900M/MT
2.0
2.0
6.15
7.1
13.35 +/- 0.5
3.0
1.5
1
1.2
2.5
2.77
1.27
2.54
13.57
21.19
(+/- 1.0)
0.64
1
Ag9900M/MT
Bottom View
14.00 11.38
1.31
All dimensions are in mm +/-0.127mm and are nominal values, unless otherwise stated.
13.57
2.54 pitch
Ag9900M/MT
PCB FOOTPRINT
14.00
1.25
Pin 1
4.0
© Silver Telecom 2020
20
V2.4 April 2020
Datasheet
Ag9900
Ultra Miniature PoE Module
Ag9900LP
5.5
7.2
2.0
2.0
8.00
3.0
(+/- 0.5)
1
1.2
1.5
(+/-0.1)
3.00
2.54
(+/- 0.25)
0.64
1.27
13.57
21.19
(+/- 1.0)
1
Ag9900LP
Bottom View
14.00 11.38
1.31
All dimensions are in mm +/-0.127mm and are nominal values, unless otherwise stated.
(Recommended PCB hole diameter = 1.1 ± 0.05)
13.57
2.54 pitch
Ag9900LP
PCB FOOTPRINT
11.38
14.00
1
The latest revision of all application notes referenced in this document can be found on the Silver Telecom website”
www.silvertel.com”.
Information published in this datasheet is believed to be correct and accurate. Silver Telecom assumes no liability for errors which
may occur or for liability otherwise arising out of use of this information or infringement of patents which may occur as a result of
such use. No license is granted by this document under patents owned by Silver Telecom or licensed from third parties by Silver
Telecom. The products, their specification and information appearing in this document are subject to change by Silver Telecom
without notice.
© Silver Telecom 2020
21
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