K = ±10% 006 = 6Vdc C = Std ESR S = 13" T&R L = Group A
represent
J = ±5%
010 = 10Vdc L = Low ESR W = Waffle
M = MIL (JAN)
significant
015 = 15Vdc
CWR11
figures 3rd
020 = 20Vdc
See page 5
digit represents
025 = 25Vdc
for additional
multiplier
035 = 35Vdc
(number of
packaging
zeros to follow)
050 = 50Vdc
options.
Reliability Grade
Qualification Termination Finish
Level
Weibull:
H = Solder Plated
0 = N/A
B = 0.1%/1000 hrs.
0 = Fused Solder
90% conf.
Plated
9 = SRC9000
C = 0.01%/1000 hrs.
8 = Hot Solder
90% conf.
Dipped
D = 0.001%/1000 hrs.
9 = Gold Plated
90% conf.
7 = Matte Sn
T = T Level
(COTS-Plus only)
Z = Non-ER
CWR11 P/N CROSS REFERENCE:
CWR11
Type
D
Voltage
Code
C = 4Vdc
D = 6Vdc
F = 10Vdc
H = 15Vdc
J = 20Vdc
K = 25Vdc
M = 35Vdc
N = 50Vdc
^
Termination
Finish
H = Solder Plated
K = Solder Fused
C = Hot Solder
Dipped
B = Gold Plated
686
Capacitance
Code
pF code:
1st two digits
represent
significant
figures 3rd digit
represents
multiplier
(number of zeros
to follow)
*
Capacitance
Tolerance
M = ±20%
K = ±10%
J = ±5%
@
Reliability
Grade
Weibull:
B = 0.1%/1000 hrs.
90% conf.
C = 0.01%/1000 hrs.
90% conf.
D = 0.001%/1000
hrs. 90% conf.
T = T Level
A = Non-ER
+
Surge Test
Option
A = 10 cycles, +25°C
B = 10 cycles,
-55°C & +85°C
C = 10 cycles,
-55°C & +85°C
before Weibull
If blank,
None required
Packaging
Bulk = Standard
\TR = 7" T&R
\TR13 = 13" T&R
\W = Waffle
See page 5
for additional
packaging
options.
SPACE LEVEL OPTIONS TO SRC9000*:
TBJ D
Type
Case
Size
686
*
006
C
L
@
9
^
++
Surge Test
Option
00 = 10 Cycles,
-55ºC & +85ºC
45 = 10 cycles,
-55ºC & +85ºC
before Weibull
Capacitance Capacitance
Voltage
Standard or Packaging Inspection Level
Code
Tolerance
Code
Low ESR
L = Group A
B = Bulk
pF code:
M = ±20% 004 = 4Vdc
Range
R = 7" T&R
1st two digits
K = ±10% 006 = 6Vdc C = Std ESR S = 13" T&R
represent
J = ±5%
010 = 10Vdc L = Low ESR W = Waffle
significant
015 = 15Vdc
figures 3rd
020 = 20Vdc
See page 5
digit represents
025 = 25Vdc
for additional
multiplier
035 = 35Vdc
(number of
packaging
zeros to follow)
050 = 50Vdc
options.
Reliability Grade
Qualification Termination Finish
Level
Weibull:
H = Solder Plated
9 = SRC9000 0 = Fused Solder
B = 0.1%/1000 hrs.
90% conf.
Plated
C = 0.01%/1000 hrs.
8 = Hot Solder
90% conf.
Dipped
D = 0.001%/1000 hrs.
9 = Gold Plated
90% conf.
*Contact factory for AVX SRC9000 Space Level SCD details.
TECHNICAL SPECIFICATIONS
Technical Data:
Capacitance Range:
Capacitance Tolerance:
Rated Voltage: (V
R
)
Category Voltage: (V
C
)
Surge Voltage: (V
S
)
Temperature Range:
Unless otherwise specified, all technical
0.1 μF to 100 μF
±5%; ±10%; ±20%
4
6
10
16
2.7
4
7
10
5.2
8
13
20
3.4
5
8
13
-55°C to +125°C
data relate to an ambient temperature of 25°C
85°C:
125°C:
85°C:
125°C:
20
13
26
16
25
17
32
20
35
23
46
28
50
33
65
40
27
TBJ Series
CWR11 - MIL-PRF-55365/8
Established Reliability, COTS-Plus & Space Level
RATING & PART NUMBER REFERENCE
CWR11 P/N
CWR11C^225*@+
CWR11C^475*@+
CWR11C^685*@+
CWR11C^106*@+
CWR11C^156*@+
CWR11C^336*@+
CWR11C^686*@+
CWR11C^107*@+
CWR11D^155*@+
CWR11D^225*@+
CWR11D^335*@+
CWR11D^475*@+
CWR11D^685*@+
CWR11D^106*@+
CWR11D^156*@+
CWR11D^226*@+
CWR11D^476*@+
CWR11D^686*@+
CWR11F^105*@+
CWR11F^155*@+
CWR11F^225*@+
CWR11F^335*@+
CWR11F^475*@+
CWR11F^685*@+
CWR11F^156*@+
CWR11F^336*@+
CWR11F^476*@+
CWR11H^684*@+
CWR11H^105*@+
CWR11H^155*@+
CWR11H^225*@+
CWR11H^335*@+
CWR11H^475*@+
CWR11H^106*@+
CWR11H^226*@+
CWR11H^336*@+
CWR11J^474*@+
CWR11J^684*@+
CWR11J^105*@+
CWR11J^155*@+
CWR11J^225*@+
CWR11J^335*@+
CWR11J^475*@+
CWR11J^685*@+
CWR11J^156*@+
CWR11J^226*@+
CWR11K^334*@+
CWR11K^474*@+
CWR11K^684*@+
CWR11K^105*@+
CWR11K^155*@+
CWR11K^225*@+
CWR11K^335*@+
CWR11K^475*@+
CWR11K^685*@+
AVX COTS-Plus P/N
TBJA 225 * 004 C
TBJ A 475 * 004 C
TBJ B 685 * 004 C
TBJ B 106 * 004 C
TBJ B 156 * 004 C
TBJ C 336 * 004 C
TBJ D 686 * 004 C
TBJ D 107 * 004 C
TBJ A 155 * 006 C
TBJ A 225 * 006 C
TBJ A 335 * 006 C
TBJ B 475 * 006 C
TBJ B 685 * 006 C
TBJ B 106 * 006 C
TBJ C 156 * 006 C
TBJ C 226 * 006 C
TBJ D 476 * 006 C
TBJ D 686 * 006 C
TBJ A 105 * 010 C
TBJ A 155 * 010 C
TBJ A 225 * 010 C
TBJ B 335 * 010 C
TBJ B 475 * 010 C
TBJ B 685 * 010 C
TBJ C 156 * 010 C
TBJ D 336 * 010 C
TBJ D 476 * 010 C
TBJ A 684 * 015 C
TBJ A 105 * 015 C
TBJ A 155 * 015 C
TBJ B 225 * 015 C
TBJ B 335 * 015 C
TBJ B 475 * 015 C
TBJ C 106 * 015 C
TBJ D 226 * 015 C
TBJ D 336 * 015 C
TBJ A 474 * 020 C
TBJ A 684 * 020 C
TBJ A 105 * 020 C
TBJ B 155 * 020 C
TBJ B 225 * 020 C
TBJ B 335 * 020 C
TBJ C 475 * 020 C
TBJ C 685 * 020 C
TBJ D 156 * 020 C
TBJ D 226 * 020 C
TBJ A 334 * 025 C
TBJ A 474 * 025 C
TBJ B 684 * 025 C
TBJ B 105 * 025 C
TBJ B 155 * 025 C
TBJ C 225 * 025 C
TBJ C 335 * 025 C
TBJ C 475 * 025 C
TBJ D 685 * 025 C
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
Parametric Specifications by Rating per MIL-PRF-55365/8
Cap
DC Rated ESR @
DCL max
DF Max
@ 120Hz Voltage
100kHz
+25ºC
+85ºC
+125ºC
+25ºC
+(85/125)ºC
μF
V
Ohms
AVX SRC9000 P/N
Case
(μA)
(μA)
(μA)
(%)
(%)
@ 25ºC
@ +85ºC @ +25ºC
TBJ A 225 * 004 C L @ 0 ^ ++ A
2.2
4
8
0.5
5
6
6
9
TBJ A 475 * 004 C L @ 0 ^ ++ A
4.7
4
8
0.5
5
6
6
9
TBJ B 685 * 004 C L @ 9 ^ ++ B
6.8
4
5.5
0.5
5
6
6
9
TBJ B 106 * 004 C L @ 9 ^ ++ B
10
4
4
0.5
5
6
6
9
TBJ B 156 * 004 C L @ 9 ^ ++ B
15
4
3.5
0.6
6
7.2
6
9
TBJ C 336 * 004 C L @ 9 ^ ++ C
33
4
2.2
1.3
13
15.6
6
9
TBJ D 686 * 004 C L @ 9 ^ ++ D
68
4
1.1
2.7
27
32.4
6
9
TBJ D 107 * 004 C L @ 9 ^ ++ D
100
4
0.9
4
40
48
8
12
TBJ A 155 * 006 C L @ 9 ^ ++ A
1.5
6
8
0.5
5
6
6
9
TBJ A 225 * 006 C L @ 9 ^ ++ A
2.2
6
8
0.5
5
6
6
6
TBJ A 335 * 006 C L @ 9 ^ ++ A
3.3
6
8
0.5
5
6
6
9
TBJ B 475 * 006 C L @ 9 ^ ++ B
4.7
6
5.5
0.5
5
6
6
9
TBJ B 685 * 006 C L @ 9 ^ ++ B
6.8
6
4.5
0.5
5
6
6
9
TBJ B 106 * 006 C L @ 9 ^ ++ B
10
6
3.5
0.6
6
7.2
6
9
TBJ C 156 * 006 C L @ 9 ^ ++ C
15
6
3
0.9
9
10.8
6
9
TBJ C 226 * 006 C L @ 9 ^ ++ C
22
6
2.2
1.4
14
16.8
6
9
TBJ D 476 * 006 C L @ 9 ^ ++ D
47
6
1.1
2.8
28
33.6
6
9
TBJ D 686 * 006 C L @ 9 ^ ++ D
68
6
0.9
4.3
43
51.6
6
9
TBJ A 105 * 010 C L @ 9 ^ ++ A
1
10
10
0.5
5
6
4
6
TBJ A 155 * 010 C L @ 9 ^ ++ A
1.5
10
8
0.5
5
6
6
6
TBJ A 225 * 010 C L @ 9 ^ ++ A
2.2
10
8
0.5
5
6
6
9
TBJ B 335 * 010 C L @ 9 ^ ++ B
3.3
10
5.5
0.5
5
6
6
9
TBJ B 475 * 010 C L @ 9 ^ ++ B
4.7
10
4.5
0.5
5
6
6
9
TBJ B 685 * 010 C L @ 9 ^ ++ B
6.8
10
3.5
0.7
7
8.4
6
9
TBJ C 156 * 010 C L @ 9 ^ ++ C
15
10
2.5
1.5
15
18
6
6
TBJ D 336 * 010 C L @ 9 ^ ++ D
33
10
1.1
3.3
33
39.6
6
9
TBJ D 476 * 010 C L @ 9 ^ ++ D
47
10
0.9
4.7
47
56.4
6
9
TBJ A 684 * 015 C L @ 9 ^ ++ A
0.68
15
12
0.5
5
6
4
6
TBJ A 105 * 015 C L @ 9 ^ ++ A
1
15
10
0.5
5
6
4
6
TBJ A 155 * 015 C L @ 9 ^ ++ A
1.5
15
8
0.5
5
6
6
9
TBJ B 225 * 015 C L @ 9 ^ ++ B
2.2
15
5.5
0.5
5
6
6
9
TBJ B 335 * 015 C L @ 9 ^ ++ B
3.3
15
5
0.5
5
6
6
8
TBJ B 475 * 015 C L @ 9 ^ ++ B
4.7
15
4
0.7
7
8.4
6
9
TBJ C 106 * 015 C L @ 9 ^ ++ C
10
15
2.5
1.6
16
19.2
6
8
TBJ D 226 * 015 C L @ 9 ^ ++ D
22
15
1.1
3.3
33
39.6
6
8
TBJ D 336 * 015 C L @ 9 ^ ++ D
33
15
0.9
5.3
53
63.6
6
9
TBJ A 474 * 020 C L @ 9 ^ ++ A
0.47
20
14
0.5
5
6
4
6
TBJ A 684 * 020 C L @ 9 ^ ++ A
0.68
20
12
0.5
5
6
4
6
TBJ A 105 * 020 C L @ 9 ^ ++ A
1
20
10
0.5
5
6
4
6
TBJ B 155 * 020 C L @ 9 ^ ++ B
1.5
20
6
0.5
5
6
6
9
TBJ B 225 * 020 C L @ 9 ^ ++ B
2.2
20
5
0.5
5
6
6
8
TBJ B 335 * 020 C L @ 9 ^ ++ B
3.3
20
4
0.7
7
8.4
6
9
TBJ C 475 * 020 C L @ 9 ^ ++ C
4.7
20
3
1
10
12
6
8
TBJ C 685 * 020 C L @ 9 ^ ++ C
6.8
20
2.4
1.4
14
16.8
6
9
TBJ D 156 * 020 C L @ 9 ^ ++ D
15
20
1.1
3
30
36
6
8
TBJ D 226 * 020 C L @ 9 ^ ++ D
22
20
0.9
4.4
44
52.8
6
9
TBJ A 334 * 025 C L @ 9 ^ ++ A
0.33
25
15
0.5
5
6
4
6
TBJ A 474 * 025 C L @ 9 ^ ++ A
0.47
25
14
0.5
5
6
4
6
TBJ B 684 * 025 C L @ 9 ^ ++ B
0.68
25
7.5
0.5
5
6
4
6
TBJ B 105 * 025 C L @ 9 ^ ++ B
1
25
6.5
0.5
5
6
4
6
TBJ B 155 * 025 C L @ 9 ^ ++ B
1.5
25
6.5
0.5
5
6
6
8
TBJ C 225 * 025 C L @ 9 ^ ++ C
2.2
25
3.5
0.6
6
7.2
6
9
TBJ C 335 * 025 C L @ 9 ^ ++ C
3.3
25
3.5
0.9
9
10.8
6
8
TBJ C 475 * 025 C L @ 9 ^ ++ C
4.7
25
2.5
1.2
12
14.4
6
9
TBJ D 685 * 025 C L @ 9 ^ ++ D
6.8
25
1.4
1.7
17
20.4
6
9
-55ºC
(%)
9
9
9
9
9
9
9
12
9
9
9
9
9
9
9
9
9
9
6
9
9
9
9
9
9
9
9
6
6
9
9
9
9
9
9
9
6
6
6
9
9
9
9
9
9
9
6
6
6
6
9
9
9
9
9
25ºC
Dissipation
Ripple
A
W
(100kHz)
0.075
0.10
0.075
0.10
0.085
0.12
0.085
0.15
0.085
0.16
0.110
0.22
0.150
0.37
0.150
0.41
0.075
0.10
0.075
0.10
0.075
0.10
0.085
0.12
0.085
0.14
0.085
0.16
0.110
0.19
0.110
0.22
0.150
0.37
0.150
0.41
0.075
0.09
0.075
0.10
0.075
0.10
0.085
0.12
0.085
0.14
0.085
0.16
0.110
0.21
0.150
0.37
0.150
0.41
0.075
0.08
0.075
0.09
0.075
0.10
0.085
0.12
0.085
0.13
0.085
0.15
0.110
0.21
0.150
0.37
0.150
0.41
0.075
0.07
0.075
0.08
0.075
0.09
0.085
0.12
0.085
0.13
0.085
0.15
0.110
0.19
0.110
0.21
0.150
0.37
0.150
0.41
0.075
0.07
0.075
0.07
0.085
0.11
0.085
0.11
0.085
0.11
0.110
0.18
0.110
0.18
0.110
0.21
0.150
0.33
Power
Typical Ripple Data by Rating
85ºC
125ºC
25ºC
Ripple
Ripple
Ripple
A
A
V
(100kHz) (100kHz) (100kHz)
0.09
0.04
0.77
0.09
0.04
0.77
0.11
0.05
0.68
0.13
0.06
0.58
0.14
0.06
0.55
0.20
0.09
0.49
0.33
0.15
0.41
0.37
0.16
0.37
0.09
0.04
0.77
0.09
0.04
0.77
0.09
0.04
0.77
0.11
0.05
0.68
0.12
0.05
0.62
0.14
0.06
0.55
0.17
0.08
0.57
0.20
0.09
0.49
0.33
0.15
0.41
0.37
0.16
0.37
0.08
0.03
0.87
0.09
0.04
0.77
0.09
0.04
0.77
0.11
0.05
0.68
0.12
0.05
0.62
0.14
0.06
0.55
0.19
0.08
0.52
0.33
0.15
0.41
0.37
0.16
0.37
0.07
0.03
0.95
0.08
0.03
0.87
0.09
0.04
0.77
0.11
0.05
0.68
0.12
0.05
0.65
0.13
0.06
0.58
0.19
0.08
0.52
0.33
0.15
0.41
0.37
0.16
0.37
0.07
0.03
1.02
0.07
0.03
0.95
0.08
0.03
0.87
0.11
0.05
0.71
0.12
0.05
0.65
0.13
0.06
0.58
0.17
0.08
0.57
0.19
0.09
0.51
0.33
0.15
0.41
0.37
0.16
0.37
0.06
0.03
1.06
0.07
0.03
1.02
0.10
0.04
0.80
0.10
0.05
0.74
0.10
0.05
0.74
0.16
0.07
0.62
0.16
0.07
0.62
0.19
0.08
0.52
0.29
0.13
0.46
85ºC
Ripple
V
(100kHz)
0.70
0.70
0.62
0.52
0.49
0.44
0.37
0.33
0.70
0.70
0.70
0.62
0.56
0.49
0.52
0.44
0.37
0.33
0.78
0.70
0.70
0.62
0.56
0.49
0.47
0.37
0.33
0.85
0.78
0.70
0.62
0.59
0.52
0.47
0.37
0.33
0.92
0.85
0.78
0.64
0.59
0.52
0.52
0.46
0.37
0.33
0.95
0.92
0.72
0.67
0.67
0.56
0.56
0.47
0.41
125ºC
Ripple
V
(100kHz)
0.31
0.31
0.27
0.23
0.22
0.20
0.16
0.15
0.31
0.31
0.31
0.27
0.25
0.22
0.23
0.20
0.16
0.15
0.35
0.31
0.31
0.27
0.25
0.22
0.21
0.16
0.15
0.38
0.35
0.31
0.27
0.26
0.23
0.21
0.16
0.15
0.41
0.38
0.35
0.29
0.26
0.23
0.23
0.21
0.16
0.15
0.42
0.41
0.32
0.30
0.30
0.25
0.25
0.21
0.18
All technical data relates to an ambient temperature of +25°C. Capacitance and DF are measured at 120Hz, 0.5V RMS with a maximum DC bias of 2.2 volts. DCL is measured at rated voltage after 5 minutes.
NOTE: AVX reserves the right to supply a higher voltage rating or tighter tolerance part in the same case size, to the same reliability standards.
28
TBJ Series
CWR11 - MIL-PRF-55365/8
Established Reliability, COTS-Plus & Space Level
RATING & PART NUMBER REFERENCE
CWR11 P/N
CWR11K^106*@+
CWR11K^156*@+
CWR11M^104*@+
CWR11M^154*@+
CWR11M^224*@+
CWR11M^334*@+
CWR11M^474*@+
CWR11M^684*@+
CWR11M^105*@+
CWR11M^155*@+
CWR11M^225*@+
CWR11M^335*@+
CWR11M^475*@+
CWR11M^685*@+
CWR11N^104*@+
CWR11N^154*@+
CWR11N^224*@+
CWR11N^334*@+
CWR11N^474*@+
CWR11N^684*@+
CWR11N^105*@+
CWR11N^155*@+
CWR11N^225*@+
CWR11N^335*@+
CWR11N^475*@+
AVX COTS-Plus P/N
TBJ D 106 * 025 C
TBJ D 156 * 025 C
TBJ A 104 * 035 C
TBJ A 154 * 035 C
TBJ A 224 * 035 C
TBJ A 334 * 035 C
TBJ B 474 * 035 C
TBJ B 684 * 035 C
TBJ B 105 * 035 C
TBJ C 155 * 035 C
TBJ C 225 * 035 C
TBJ C 335 * 035 C
TBJ D 475 * 035 C
TBJ D 685 * 035 C
TBJ A 104 * 050 C
TBJ B 154 * 050 C
TBJ B 224 * 050 C
TBJ B 334 * 050 C
TBJ C 474 * 050 C
TBJ C 684 * 050 C
TBJ C 105 * 050 C
TBJ D 155 * 050 C
TBJ D 225 * 050 C
TBJ D 335 * 050 C
TBJ D 475 * 050 C
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
# @ 0 ^ ++
Parametric Specifications by Rating per MIL-PRF-55365/8
Cap
DC Rated ESR @
DCL max
DF Max
@ 120Hz Voltage
100kHz
+25ºC
+85ºC
+125ºC
+25ºC
+(85/125)ºC
μF
V
Ohms
AVX SRC9000 P/N
Case
(μA)
(μA)
(μA)
(%)
(%)
@ 25ºC
@ +85ºC @ +25ºC
TBJ D 106 * 025 C L @ 9 ^ ++ D
10
25
1.2
2.5
25
30
6
8
TBJ D 156 * 025 C L @ 9 ^ ++ D
15
25
1
3.8
38
45.6
6
9
TBJ A 104 * 035 C L @ 9 ^ ++ A
0.1
35
24
0.5
5
6
4
6
TBJ A 154 * 035 C L @ 9 ^ ++ A
0.15
35
21
0.5
5
6
4
6
TBJ A 224 * 035 C L @ 9 ^ ++ A
0.22
35
18
0.5
5
6
4
6
TBJ A 334 * 035 C L @ 9 ^ ++ A
0.33
35
15
0.5
5
6
4
6
TBJ B 474 * 035 C L @ 9 ^ ++ B
0.47
35
10
0.5
5
6
4
6
TBJ B 684 * 035 C L @ 9 ^ ++ B
0.68
35
8
0.5
5
6
4
6
TBJ B 105 * 035 C L @ 9 ^ ++ B
1
35
6.5
0.5
5
6
4
6
TBJ C 155 * 035 C L @ 9 ^ ++ C
1.5
35
4.5
0.5
5
6
6
8
TBJ C 225 * 035 C L @ 9 ^ ++ C
2.2
35
3.5
0.8
8
9.6
6
8
TBJ C 335 * 035 C L @ 9 ^ ++ C
3.3
35
2.5
1.2
12
14.4
6
8
TBJ D 475 * 035 C L @ 9 ^ ++ D
4.7
35
1.5
1.7
17
20.4
6
8
TBJ D 685 * 035 C L @ 9 ^ ++ D
6.8
35
1.3
2.4
24
28.8
6
9
TBJ A 104 * 050 C L @ 9 ^ ++ A
0.1
50
22
0.5
5
12
6
8
TBJ B 154 * 050 C L @ 9 ^ ++ B
0.15
50
17
0.5
5
6
4
6
TBJ B 224 * 050 C L @ 9 ^ ++ B
0.22
50
14
0.5
5
6
4
6
TBJ B 334 * 050 C L @ 9 ^ ++ B
0.33
50
12
0.5
5
6
4
6
TBJ C 474 * 050 C L @ 9 ^ ++ C
0.47
50
8
0.5
5
6
4
6
TBJ C 684 * 050 C L @ 9 ^ ++ C
0.68
50
7
0.5
5
6
4
6
TBJ C 105 * 050 C L @ 9 ^ ++ C
1
50
6
0.5
5
6
4
6
TBJ D 155 * 050 C L @ 9 ^ ++ D
1.5
50
4
0.8
8
9.6
6
8
TBJ D 225 * 050 C L @ 9 ^ ++ D
2.2
50
2.5
1.1
11
13.2
6
8
TBJ D 335 * 050 C L @ 9 ^ ++ D
3.3
50
2
1.7
17
20.4
6
9
TBJ D 475 * 050 C L @ 9 ^ ++ D
4.7
50
1.5
2.4
24
28.8
6
9
-55ºC
(%)
9
9
6
6
6
6
6
6
6
9
9
9
9
9
8
6
6
6
6
6
6
9
9
9
9
25ºC
Dissipation
Ripple
A
W
(100kHz)
0.150
0.35
0.150
0.39
0.075
0.06
0.075
0.06
0.075
0.06
0.075
0.07
0.085
0.09
0.085
0.10
0.085
0.11
0.110
0.16
0.110
0.18
0.110
0.21
0.150
0.32
0.150
0.34
0.075
0.06
0.085
0.07
0.085
0.08
0.085
0.08
0.110
0.12
0.110
0.13
0.110
0.14
0.150
0.19
0.150
0.24
0.150
0.27
0.150
0.32
Power
Typical Ripple Data by Rating
85ºC
125ºC
25ºC
Ripple
Ripple
Ripple
A
A
V
(100kHz) (100kHz) (100kHz)
0.32
0.14
0.42
0.35
0.15
0.39
0.05
0.02
1.34
0.05
0.02
1.25
0.06
0.03
1.16
0.06
0.03
1.06
0.08
0.04
0.92
0.09
0.04
0.82
0.10
0.05
0.74
0.14
0.06
0.70
0.16
0.07
0.62
0.19
0.08
0.52
0.28
0.13
0.47
0.31
0.14
0.44
0.05
0.02
1.28
0.06
0.03
1.20
0.07
0.03
1.09
0.08
0.03
1.01
0.11
0.05
0.94
0.11
0.05
0.88
0.12
0.05
0.81
0.17
0.08
0.77
0.22
0.10
0.61
0.25
0.11
0.55
0.28
0.13
0.47
85ºC
Ripple
V
(100kHz)
0.38
0.35
1.21
1.13
1.05
0.95
0.83
0.74
0.67
0.63
0.56
0.47
0.43
0.40
1.16
1.08
0.98
0.91
0.84
0.79
0.73
0.70
0.55
0.49
0.43
125ºC
Ripple
V
(100kHz)
0.17
0.15
0.54
0.50
0.46
0.42
0.37
0.33
0.30
0.28
0.25
0.21
0.19
0.18
0.51
0.48
0.44
0.40
0.38
0.35
0.32
0.31
0.24
0.22
0.19
All technical data relates to an ambient temperature of +25°C. Capacitance and DF are measured at 120Hz, 0.5V RMS with a maximum DC bias of 2.2 volts. DCL is measured at rated voltage after 5 minutes.
NOTE: AVX reserves the right to supply a higher voltage rating or tighter tolerance part in the same case size, to the same reliability standards.
I want to use LM334 as a constant current source for a shock wave signal sensor, but when the signal changes suddenly, the current has a jitter. Since the shock wave signal lasts for a short time (abo...
Why do the high and low levels of the waveform become smaller after passing through a resistor? Is it that the larger the resistance, the greater the voltage drop?...
In recent years, lighting has become an important area that countries around the world are targeting to promote energy conservation and environmental protection. According to statistics, about 20% ...[Details]
We know that microcontroller development tools generally include real-time online emulators and programmers. Among them, online emulators are very good tools, but they are also more expensive...[Details]
Editor's note: In order to help technicians or engineers who have knowledge of PIC microcontroller assembly language quickly master the method of using C language to program PIC microcontrollers, t...[Details]
Smart lighting control systems provide high controllability for various buildings and further enhance the level of green energy. They are the core products of energy conservation and digital techn...[Details]
With the continuous consumption of earth's energy and the scarcity of resources, the harm of greenhouse effect to human beings, and the serious pollution of the atmosphere to the earth, the intern...[Details]
The traditional display screen using 51 single-chip microcomputer to control LED dot matrix has relatively simple functions. If it is to achieve diversified functions, it often takes a lot of time ...[Details]
FPGAs are used in 81% of electronic systems, including many commercial and defense products, and most FPGAs use BGA packaging. The BGA packaging is characterized by small solder balls and small sol...[Details]
Abstract: The output of high-range acceleration sensor is less than 10 mV under the excitation of small signal. The noise of traditional test system may cover such small voltage signal, so that hig...[Details]
1 Load Regulation
Changes in power supply load will cause changes in power supply output. When the load increases, the output decreases, and vice versa, when the load decreases, the output inc...[Details]
introduction
The core features of mobile value-added service products are mobility, immediacy and personalization. Mobile value-added services are a new service mode that is rapidly developing...[Details]
1 Introduction
At present, advocating health has become the focus of people's attention, and the emergence of treadmills has become more and more popular. People can exercise at home or in the ...[Details]
The principles to be followed are as follows:
(1) In terms of component layout, related components should be placed as close as possible. For example, clock generators, crystal oscillat...[Details]
Abstract: Based on the analysis of the characteristics of the IRIG-B (DC) code type, a design method for IRIG-B (DC) time code decoding is proposed. This method consists of a small number of periph...[Details]
Traditional synthesis techniques are increasingly unable to meet the needs of today's very large and complex FPGA designs implemented in 90nm and below process nodes. The problem is that traditio...[Details]
In recent years, the application of single-chip microcomputer systems in the field of industrial measurement and control has become more and more extensive. However, for industrial sites with harsh...[Details]
Analog electronics
京公网安备 11010802033920号
EEWORLD
