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1410K1000101MCRE03

Feed Through Capacitor, 2 Function(s), 100V, EIA STD PACKAGE SIZE 1410

器件类别:模拟混合信号IC    过滤器   

厂商名称:Knowles

厂商官网:http://www.knowles.com

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器件参数
参数名称
属性值
厂商名称
Knowles
包装说明
EIA STD PACKAGE SIZE 1410
Reach Compliance Code
_compli
其他特性
FLEXICAP TERMINATION
电容
100 µF
滤波器类型
FEED THROUGH CAPACITOR
高度
2 mm
最小绝缘电阻
10000 MΩ
JESD-609代码
e3
长度
3.6 mm
制造商序列号
X2Y
安装类型
SURFACE MOUNT
功能数量
2
最高工作温度
125 °C
最低工作温度
-55 °C
包装方法
REEL
物理尺寸
L3.6XB2.5XH2.0 (mm)/L0.142XB0.098XH0.079 (inch)
额定电压
100 V
端子面层
MATTE TIN
宽度
2.5 mm
文档预览
Integrated
Passive Components
Balanced Line EMI Chip
X2Y
The Syfer Balanced Line Chip is a 3 terminal EMI chip device. The
revolutionary design provides simultaneous line-to-line and line-to-
ground filtering, using a single ceramic chip. In this way, differential
and common mode filtering are provided in one device. Capable of
replacing 2 or more conventional devices, it is ideal for balanced lines,
twisted pairs and dc motors, in automotive, audio, sensor and other
applications.
These filters can prove invaluable in meeting stringent EMC demands
particularly in automotive applications.
Specifications
Dielectric
Electrical Configuration
Capacitance Measurement
Typical Capacitance Matching
Temperature Rating
Dielectric Withstand Volage
Insulation Resistance
Termination Material
X7R or C0G/NP0
Multiple capacitance
At 1000hr point
Better than 5%
-55°C to 125°C
2.5 x Rated Volts for 5 secs.
Charging current limited to 50mA Max.
100Gohms or 1000s (whichever is the less)
100% matte tin over nickel
L
T
Advantages
Replaces 2 or 3 capacitors with one device
Matched capacitance line to ground on both lines
Low inductance due to cancellation effect
Capacitance line to line
Differential and common mode attenuation
Effects of temperature and voltage variation eliminated
Effect of ageing equal on both lines
High current capability
W
L1
L2
INPUT 1
A
C1
GROUND
C1
C2
A
Applications
Balanced lines
Twisted pairs
EMI Suppression on DC motors
Sensor/transducer applications
Wireless communications
Audio
INPUT 2
B
B
Chip
Size
0603*
0805
1206
1410
1812
2220
L
1.6±0.2 (0.063±0.008)
2.0±0.3 (0.08±0.012)
3.2±0.3 (0.126±0.012)
3.6±0.3 (0.14±0.012)
4.5±0.35 (0.18±0.014)
5.7±0.4 (0.22±0.016)
W
0.8±0.2 (0.03±0.008)
1.25±0.2 (0.05±0.008)
1.60±0.2 (0.063±0.008)
2.5±0.3 (0.1±0.012)
3.2±0.3 (0.126±0.012)
5.0±0.4 (0.2±0.016)
T
0.5±0.15 (0.02±0.006)
1.0±0.15 (0.04±0.006)
1.1±0.2 (0.043±0.008)
2 max. (0.08 max.)
2 max. (0.08 max.)
2.5 max. (0.1 max.)
L1
0.3±0.2 (0.012±0.008)
0.5±0.25 (0.02±0.01)
0.95±0.3 (0.037±0.012)
1.20±0.3 (0.047±0.012)
1.5±0.35 (0.06±0.014)
2.25±0.4 (0.09±0.016)
L2
0.2±0.1 (0.008±0.004)
0.3±0.15 (0.012±0.006)
0.5±0.25 (0.02±0.01)
0.5±0.25 (0.02±0.01)
0.5±0.25 (0.02±0.01)
0.75±0.25 (0.03±0.01)
Recommended Solder Lands
Insertion Loss Characteristics (common mode)
Typical 50 ohm system
80
220nF
4.7nF
2.2nF
1nF
470pF
220pF
100pF
47pF
22pF
B
C
A
Insertion Loss (dB)
60
100nF
47nF
22nF
D
40
10nF
Chip Size
0603*
0805
1206
1410
1812
2220
A
0.6 (0.024)
0.95 (0.037)
1.2 (0.047)
2.05 (0.08)
2.65 (0.104)
4.15 (0.163)
Dimensions mm (inches)
B
C
D
0.6 (0.024) 0.4 (0.016) 0.2 (0.008)
0.9 (0.035) 0.3 (0.012) 0.4 (0.016)
0.9 (0.035) 0.6 (0.024) 0.8 (0.03)
1.0 (0.04) 0.7 (0.028) 0.9 (0.035)
1.4 (0.055) 0.8 (0.03) 1.4 (0.055)
1.4 (0.055) 1.2 (0.047) 1.8 (0.071)
20
0
0.1
1
10
100
1000
Frequency (MHz)
*
The 0603 chip size is a development item. All technical information should
be considered provisional and subject to change. Refer to Sales office.
FILTSMX2Y.ver2
notes
Integrated
Passive Components
Balanced Line EMI Chip
X2Y
06
12
10
14
20
22
05
08
12
18
100V
3
60
*0
e
alu
pV
Ca C1 %)
20
e
alu
pV
Ca C2 %)
20
X7R
X7R
100V
C0G
X7R
X7R
X7R
100V
C0G
C0G
C0G
C0G
1000
4000
Voltage
100V
50V
25V
16V
Reeled
Quantity
178mm (7”)
330mm (13”)
4000
16000
3000
12000
2500
10000
2000
8000
notes
*
The 0603 chip size is a development item. All technical information should
be considered provisional and subject to change. Refer to Sales office.
FILTSMX2Y.ver2
C0G
1000
4000
X7R
100V
e
od
pC
Ca
100
120
150
180
220
270
330
390
470
560
680
820
101
121
151
181
221
271
331
391
471
561
681
821
102
122
152
182
222
272
332
392
472
562
682
822
103
123
153
183
223
273
333
393
473
563
683
823
104
124
154
184
224
274
334
394
474
564
684
824
105
125
10pF
12
15
18
22
27
33
39
47
56
68
82
100
120
150
180
220
270
330
390
470
560
680
820
1.0nF
1.2
1.5
1.8
2.2
2.7
3.3
3.9
4.7
5.6
6.8
8.2
10
12
15
18
22
27
33
39
47
56
68
82
100
120
150
180
220
270
330
390
470
560
680
820
1µF
1.2
5pF
6
7.5
9
11
13.5
16.5
19.5
23.5
28
34
41
50
60
75
90
110
135
165
195
235
280
340
410
0.5nF
0.6
0.75
0.9
1.1
1.35
1.65
1.95
2.35
2.8
3.4
4.1
5
6
7.5
9
11
13.5
16.5
19.5
23.5
28
34
41
50
60
75
90
110
135
165
195
235
280
340
410
0.5µF
0.6
50V
50V
100V
100V
100V
100V
100V
100V
Integrated
Passive Components
Balanced Line EMI Chip
X2Y
The Syfer Balanced Line EMI chip has a unique internal architecture
which provides unbeatable EMC performance for dual line data
transmission.
A typical application for dual line data transmission would see a
board layout using decoupling chip capacitors or 3 terminal
feedthrough chips as shown in Fig 1.
INPUT 1
INPUT 1
INPUT 2
INPUT 3
INPUT 4
INPUT 4
CHIP CAPACITORS
Fig 1
The Balanced Line EMI chip replaces decoupling capacitors or 3
terminal feedthrough chips on a 1 for 2 basis and provides line to
line (differential mode) decoupling. Fig 2.
C1
EARTH
TRACKS
INPUT 2
INPUT 3
EARTH
TRACKS
3 TERMINAL CHIPS
LINE A
C2
INPUT 1
INPUT 2
INPUT 3
INPUT 4
BALANCED LINE
EMI CHIP
Fig 2
The internal structure furnishes a reduced inductance when
compared to that of a conventional capacitor. This is a result of the
novel internal electrode structure which inherently reduces the
inductance by the cancellation effect of opposing currents in close
proximity.
The capacitance line to ground (common mode) is closely matched
due to the symmetry within the design. As the device includes line
to ground capacitance for both lines, any temperature, ageing and
voltage effects will have an equal influence on both lines therefore
maintaining balanced decoupling.
The construction also allows a capacitance between lines as well as
to ground as shown in Fig 3.
LINE B
EARTH
TRACKS
C1
Fig 3
C2, the line to line capacitance, is half the line to ground
capacitance thus providing coupling of high frequency interference
between balanced lines.
Because the part acts as a decoupling device, the current limitations
of a standard 3 terminal chip do not apply. The single line 3
terminal feedthrough chip carries the signal current through the
very thin feedthrough electrodes within the device which have
limited DC resistance and so can cause excessive heating, hence the
maximum permissible current is often limited to around 300 mA for
a 1206 device. The dual line 3 terminal chip is in by-pass across
two lines and so is unaffected by high signal currents.
Table 1 offers a comparison of decoupling devices and
demonstrates how the Balanced Line EMI chip extends the options
for EMC circuit protection.
Component
Chip capacitor
3 terminal
feedthrough
Advantages
Industry standard
Feedthrough
Lower Inductance
Very low inductance
Replaces 2 (or 3) components
Negates the effects of
temperature, voltage and ageing
Provides both common mode and
differential mode attenuation
Disadvantages
Requires 1 per line
High inductance
Capacitance matching problems
Current limited
Applications
By-pass
Low frequency
Feedthrough
Unbalanced lines
High frequency
By-pass
Balanced lines
High frequency
DC electric motors
Balanced line
EMI chip
Not for unbalanced signal lines
Table 1
FILTSMX2Y.ver2
Integrated
Passive Components
Balanced Line EMI Chip
X2Y
Application Note
One of the significant features of this product is its extremely low
inductance, making it particularly suitable for high speed digital
applications and for reduction of common mode currents for power
line applications. Inductance cancellation, due to the effect of
opposing current flow across the device, results in a typical line to
line inductance of around 100pH, with a corresponding line to
ground inductance of 50pH.
The Balanced Line EMI chip satisfies the need for high speed
communications systems using balanced lines or twisted pairs
offering low inductance (therefore high frequency operation),
reduced board space, reduced component count and an
unparalleled performance.
Ordering Information
1206
Chip Size
Reference
J
Termination
J = Nickel
Barrier
Y = FlexiCap™
100
Voltage
016 = 16 volts
025 = 25 volts
050 = 50 volts
100 = 100 volts
0222
Capacitance
Expressed in picofarads (pF).
First digit is 0.
Second and third digits are significant
figures of capacitance code.
The fourth digit is number of zeros
following.
Example: 0222=2200pF.
M
Tolerance
M= ±20%
X
Dielectric
C = C0G
X = X7R
T
Packaging
T =178mm
(7”) reel
R =330mm
(13”) reel
B =Bulk
E03
Balanced Line
EMI Chip
Syfer Technology are able to provide comprehensive applications
Technical and application papers are available on request from
and design in support.
the Sales Office.
Manufactured in the UK by Syfer Technology Limited under licence from X2Y attenuators LLC.
FILTSMX2Y.ver2
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