Remark: Reference level for the relative attenuation
arel
of the
TFS 140
is the minimum of the pass band attenuation
amin.
The minimum
of the pass band attenuation
amin
is defined as the insertion loss
ae
. The reference frequency
fc
is the arithmetic mean value of the upper
and lower frequencies at the
3 dB
filter attenuation level relative to the insertion loss
ae.
The temperature coefficient of frequency
Tc
f
is valid
both for the reference frequency
fc
and the frequency response of the filter in the operating temperature range. The frequency shift of the
filter in the operating temperature range is not included in the production tolerance scheme
Data
Insertion loss
(Reference level)
Centre frequency
ae
typ. value
22,5 dB
140,01 MHz
tolerance / limit
max.
24
dB
fc
at ambient temperature T
A
(f
CAT
)
140,00 ± 0,10 MHz
f
C
- 3,0 MHz ... f
C
+ 3,0 MHz
Pass band
at ambient temperature T
A
:
PB
Amplitude ripple (p-p):
f
C
– 2,6 MHz ... f
C
+ 2,6 MHz
f
C
± 2,6 MHz ... f
C
± 2,8 MHz
Bandwidth
at ambient temperature T
A
:
1 dB
3 dB
3 dB
20 dB
40 dB
45 dB
Relative attenuation
f
C
f
C
f
C
f
C
f
C
f
C
f
C
f
C
f
C
±
±
±
±
±
-
+
+
+
2,6
2,8
3,2
4,1
4,5
65
12
75
130
MHz ... f
C
± 2,8
MHz ... f
C
± 3,0
MHz ... f
C
± 4,1
MHz ... f
C
± 4,5
MHz ... f
C
± 12
MHz ... f
C
- 12
MHz ... f
C
+ 75
MHz ... f
C
+ 130
MHz ... f
C
+ 460
arel
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
-
dB
dB
dB
dB
dB
dB
dB
dB
0,5 dB
0,7 dB
5,76 MHz
6,24 MHz
6,24 MHz
6,30 MHz
7,95 MHz
8...8,6 MHz
max.
max.
min.
min.
max.
max.
max.
1
1
5,6
6,0
6,4
8,2
9,0
dB
dB
MHz
MHz
MHz
MHz
MHz
45
48...53
75...55
55...75
48...50
70
max.
max.
min.
min.
min.
min.
min.
min.
max.
max.
1
3
3
40
45
50
50
47
2,0
80
dB
dB
dB
dB
dB
dB
dB
dB
µs
ns
Group delay ( mean value in PB ):
Group delay ripple in PB (p-p):
Deviation from linear phase in PB band (p-p):
VSWR (S11) / (S22) in PB :
Triple transit attenuation compared to main signal
Crosstalk
Frequency inversion temperature ( T
o
)
Temperature coefficient of frequency ( Tc
f
)
Frequency deviation of fc over temperature: * )
Operating temperature range
Storage temperature range
Input power
1,84 µs
50...60
ns
4..4,5 ° (r.m.s. 1,3°)
(2:1) / (2:1)
49 dB
55...60 dB
25° C
-0,045
ppm/K²
∆f
c(Hz) = Tc
f
(ppm/K) x (T - T
o
)² x
f
To
(MHz)
- 25 °C ... + 80 °C
- 40 °C ... + 85 °C
max.
20
dBm
*) The terminating impedances depend on parasitics and q-values of matching elements and the board used, and are to be understood as
reference values only. Should there be additional questions do not hesitate to ask for an application note or contact our design team.
**)
f
To
is reference frequence fc at frequency inversion temperature (T
o
)
Generated:
Checked/Approved:
Dunzow W.
Dr. Bert Wall
VI TELEFILTER
Potsdamer Straße 18
D 14 513 TELTOW / Germany
Tel: (+49) 3328 4784-0 / Fax: (+49) 3328 4784-30
E-Mail:
tft@telefilter.com
Vectron International, Inc.
267 Lowell Road
Hudson, NH 03051 / USA
Tel: (603) 598-0070 Fax: (603) 598-0075
E-Mail:
vti@vtinh.com
VI TELEFILTER reserves the right to make changes to the product(s) and/or information contained herein without notice. No liability is assumed as a result of
their use or application. No rights under any patent accompany the sale of any such product(s) or information
file name: Tfs 140.doc
Version 2.3
05.03.2002
VI TELEFILTER
Filter specification
TFS 140
2/4
3. Construction and pin connection :
( all dimensions in mm)
22,5 Max.
5,0 max.
5,6 max.
2,54 ± 0,2
6x2,54 = 15,62
13 max.
0,45 Dia.
7,62
TFS 140
P22
1
2
7
Pin
Pin
Pin
Pin
Pin
14
9
8
Date-code:
M
N
P
...
Year+week
2000
2001
2002
...
Date-code
14
1
8
7
2, 9
Input
Input RF Return
Output
Output RF Return
Pakage Ground
4. 50
Ω
matching network ( please refer to the application note for further details ) :
L
1
= 320
±
20 nH
50
Ω
14
9
8
L
2
= 320
±
20 nH
50
Ω
TFS
140
P22
L
3
= 330 nH; Q = 50
1 2
R
1
= 6,2 kΩ;
C
1p
= 2,5 pF;
R
1
= R
1
= 6,2 kΩ .
7
L
4
= 330 nH; Q = 50
R
2
= 6,2 kΩ;
C
1p
= 2,5 pF;
VI TELEFILTER
Potsdamer Straße 18
D 14 513 TELTOW / Germany
Tel: (+49) 3328 4784-0 / Fax: (+49) 3328 4784-30
E-Mail:
tft@telefilter.com
Vectron International, Inc.
267 Lowell Road
Hudson, NH 03051 / USA
Tel: (603) 598-0070 Fax: (603) 598-0075
E-Mail:
vti@vtinh.com
VI TELEFILTER reserves the right to make changes to the product(s) and/or information contained herein without notice. No liability is assumed as a result of
their use or application. No rights under any patent accompany the sale of any such product(s) or information
file name: Tfs 140.doc
Version 2.3
05.03.2002
VI TELEFILTER
5. Stability characteristics :
Filter specification
TFS 140
3/4
After the following tests the filter shall meet the whole specification:
1. Shock:
500g, 18 ms, half sine wave, 3 shocks each plane;
DIN IEC 68 T2 - 27
10 Hz to 500 Hz, 0,35 mm or 5g respectively, 1 octave per min, 10 cycles per plan, 3 plans;
DIN IEC 68 T2 - 6
2. Vibration:
3. Change of
temperature:
-55 °C to 125°C / 30 min. each / 10 cycles
DIN IEC 68 part 2 – 14 Test N
4. Resistance to
solder heat (reflow):
reflow possible: twice max.;
for temperature conditions, please refer to the attached "Air reflow temperature conditions"
on page 4;
VI TELEFILTER
Potsdamer Straße 18
D 14 513 TELTOW / Germany
Tel: (+49) 3328 4784-0 / Fax: (+49) 3328 4784-30
E-Mail:
tft@telefilter.com
Vectron International, Inc.
267 Lowell Road
Hudson, NH 03051 / USA
Tel: (603) 598-0070 Fax: (603) 598-0075
E-Mail:
vti@vtinh.com
VI TELEFILTER reserves the right to make changes to the product(s) and/or information contained herein without notice. No liability is assumed as a result of
their use or application. No rights under any patent accompany the sale of any such product(s) or information
file name: Tfs 140.doc
Version 2.3
05.03.2002
VI TELEFILTER
Filter specification
TFS 140
4/4
6. Air reflow temperature conditions :
1st and 2nd air reflow profile
Name:
Temperature:
Time:
pre-heating periods
150 °C - 170 °C
60 sec. - 90 sec.
main-heating periods
over 200 °C
20 sec. - 25 sec.
peak temperature
255 °C ± 5 °C
Air reflow profile
260
240
220
200
temperature / °C
180
160
140
120
100
80
60
40
20
0
0
20
40
60
80
100
120
time / sec.
140
160
180
200
220
240
Table for temperature vs. time during the air reflow process
Tolerance of temperatures: ± 5 °C
time / sec.
0
10
20
30
40
50
60
70
80
90
100
110
120
130
temperature / °C
23
34
46
60
80
103
121
134
143
150
154
156
158
159
time / sec.
140
150
160
170
180
190
195
200
205
210
215
220
230
240
temperature / °C
160
161
164
170
180
205
230
255
230
205
180
165
140
120
VI TELEFILTER
Potsdamer Straße 18
D 14 513 TELTOW / Germany
Tel: (+49) 3328 4784-0 / Fax: (+49) 3328 4784-30
E-Mail:
tft@telefilter.com
Vectron International, Inc.
267 Lowell Road
Hudson, NH 03051 / USA
Tel: (603) 598-0070 Fax: (603) 598-0075
E-Mail:
vti@vtinh.com
VI TELEFILTER reserves the right to make changes to the product(s) and/or information contained herein without notice. No liability is assumed as a result of
their use or application. No rights under any patent accompany the sale of any such product(s) or information
file name: Tfs 140.doc
Version 2.3
05.03.2002
VI TELEFILTER
Filter specification
TFS 140
5/4
7. History :
Version
1.0
2.0
2.1
Reason of changes
Generate Development Specification .
Generate Preliminary Specification of TFS 140.
Generate Filter Specification of TFS 140 :
- edit termination impedance values and matching configuration
- change matching networks ;
- change limit values of ILo: from max.23 dB to max.24 dB .
Correct termination impedances .
add input power : max. 20dBm.
Name
Dunzow W.
Dunzow W.
Dunzow W.
Date
20.04.1997
21.09.1998.
11.09.2000.
2.2
2.3
Dunzow W.
Dunzow W.
20.11.2000
05.03.2002.
VI TELEFILTER
Potsdamer Straße 18
D 14 513 TELTOW / Germany
Tel: (+49) 3328 4784-0 / Fax: (+49) 3328 4784-30
E-Mail:
tft@telefilter.com
Vectron International, Inc.
267 Lowell Road
Hudson, NH 03051 / USA
Tel: (603) 598-0070 Fax: (603) 598-0075
E-Mail:
vti@vtinh.com
VI TELEFILTER reserves the right to make changes to the product(s) and/or information contained herein without notice. No liability is assumed as a result of
their use or application. No rights under any patent accompany the sale of any such product(s) or information
I want to convert the VGA signal from the graphics card into a differential RGB signal. Is there any suitable solution? What kind of chip should be used? Please let me know if you know....
[i=s]This post was last edited by jihw1990 on 2018-1-18 13:53[/i] Does anyone have the python code for the pyboard driver[/size][/font][/color][font=Montserrat, sans-serif][color=#000000][size=22px]LC...
Xiao Xiaobai laughed at me for having no basic knowledge...
I don’t know what the basics are, and what level is required to master the basics.
Everyone, please share your opinions....
Emergency hand-held lamps powered by 6V maintenance-free batteries are widely used in rural areas. The charger used is a transformer step-down and single diode half-wave rectifier, and the charging...[Details]
Traditional broadcasting systems generally need to be operated manually at a fixed time, and can only realize one-way broadcasting with few functions. Traditional bell ringing equipment has a singl...[Details]
1. Circuit composition
The whole circuit consists of two parts:
1. Power saving control circuit
As shown in the figure below. Including delay circuit and drive circuit.
(1) Delay ci...[Details]
1. Introduction
With the growth of parking demand, the scale of parking lots is becoming larger and larger. A lot of research has been done on intelligent parking lots in China, but most of th...[Details]
Do you often have to add brake fluid to your car's brakes? The fact that you need to pump out the brake fluid to make sure there is no gas in the brake fluid line may not be done by the car owner h...[Details]
Converged processors meet scalability requirements
In current embedded system design, solutions based on MCU, DSP, FPGA and ASIC account for more than 90% of the market share. These solutions ...[Details]
1 Introduction
With the acceleration of the pace of urban modernization, society has higher requirements for urban road lighting and urban lighting projects. The state has clearly required tha...[Details]
For a long time, due to the limitation of hardware conditions, the display devices of traditional small handheld devices such as PDA are usually monochrome LCD, and the user interface is very simpl...[Details]
This paper establishes a fuel cell engine test platform based on the NI integrated hardware and software environment. This platform can realize the test and control of fuel cell engines and their a...[Details]
1. Introduction to CIF Board
Fieldbus integration based on PC system
Whether it is a master or a slave, fieldbus has won unanimous praise in the field of PC-based automation. For more...[Details]
This week, Microsoft held its 2012 Microsoft Worldwide Partner Conference (WPC) in Toronto, Canada. At the conference, Microsoft showed its new products and services to partners around the world. A...[Details]
1 Introduction
In recent years, there have been many major advances in the production technology and processes of automotive headlights, which have greatly improved the performance of automoti...[Details]
With the rapid development of intelligent control technology, computers and information technology, the trend of information appliances IA (Information Application), computers and communications integ...[Details]
Different initialization between C8051F and 80C51 series microcontrollers
In the past 30 years, major electronic component manufacturers in the world have launched their own unique single-chip...[Details]
introduction
At present, measuring instruments are developing towards networking, and each individual embedded instrument will become a node on the Internet. This system realizes the network...[Details]
Talking
京公网安备 11010802033920号
EEWORLD
