ETC P1681T

SMT POWER INDUCTORS
For Use with Volterra's Chipset
Two package sizes
Height: .125" and .177" Max
Footprint: .276" x .250" and .340" x .250" Max
Current Range: up to 15 Arms
Typical Energy Storage Density: 1450 µJ/in3
Frequency Range: 300 kHz to 2 MHz
Electrical Specifications @ 25°C — Operating Temperature -40°C to 125°C
Part
Number
Inductance
@Irated
(nH ± 20%)
Irated
(ADC)
P1681T
P2005T
P2004T
95
142.5
190
15
15
15
DCR
Ω)
(mΩ
1
Typical
.31
.45
.45
Max
.39
.56
.56
Inductance
@0ADC
(nH ± 20%)
100
150
200
Saturation Current 2
(A)
-40°C
18.2
18.2
17
25°C
18
18
16.8
125°C
16.2
16.2
15.12
Heating
Current 3
(A)
Trise
Factor K0 4
(cm2)
15
15
15
1.0032
2.2458
2.2458
P2004T/P2005T
P1681T
.130
3,30
.250 MAX
6,35
P2004/5T
Date Code
Country of Origin
(Volta 2)
.010
0,25
2X.065
1,65
.110
2,80
.250 MAX
6,35
.177 MAX
4,50
.125 MAX
3,18
.010
0,25
Factor K2
.07381
.05961
.07949
.340 MAX
8,64
.276 MAX
7,01
Date Code
Country of Origin
Factor K1
.00319
.00638
.00638
Schematic
Mechanicals
P1681T (Volta 1)
Core Loss 4
P1681T
P2004T & P2005T
Weight ................0.464 grams ................0.945 grams
Tape & Reel.............1500/reel .....................1000/reel
2X.079
2,01
.150
3,81
.135
3,43
.100
2,54
.150
3,81
.280
7,11
.350
8,89
SUGGESTED PAD LAYOUT
SUGGESTED PAD LAYOUT
Dimensions: Inches
mm
Unless otherwise specified, all tolerances are ± .010
0,25
US 858 674 8100 • UK 44 1483 401 700 • France 33 3 84 35 04 04 • Singapore 65 287 8998 • Taiwan 886 2 2698 0228 • Hong Kong 852 2788 6588 • http://www.pulseeng.com
PC500.B (5/02)
28
SMT POWER INDUCTORS
For Use with Volterra's Chipset
Notes from Tables
1. The rated current as listed is either the saturation current or the
heating current depending on which value is lower.
2. The saturation current is the current which causes the
inductance to drop by 10% at the stated ambient temperatures
(-40°C, 25°C, 125°C). This current is determined by placing the
component in the specified ambient environment and applying
a short duration pulse current (to eliminate self-heating effects)
to the component.
3. The heating current is the dc current which causes the temperature of the part to increase by approximately 30°C. This current
is determined by mounting the component on a PCB with .25"
wide, 3 oz. equivalent copper traces, and applying the current
to the device for 30 minutes.
4. In high volt*time applications, additional heating in the
component can occur due to core losses in the inductor
which may neccessitate derating the current in order to limit
the temperature rise of the component. In order to determine
the approximate total losses (or temperature rise) for a given
application both copper losses and core losses should be
taken into account.
Estimated Temperature Rise:
.833
Trise = Coreloss (mW) + DCRloss (mW)
(°C)
K0
Coreloss = K1 *
(Fsw(kHz))1.6688
* (K2 * dI)2.17 (mW)
DCRloss = Irms2 * DCR(mΩ) (mW)
Irms =
IDC2 + dI
2
½
(Arms)
2
Fsw(kHz) = switching frequency (kHz)
dI = delta I across the component (A)
The temperature of the component (ambient temperature +
temperature rise) should be within the listed operating
temperature range.
Inductance vs Current Characteristics
Percentage of Initial Inductance
P2
P1
120
P3
100
80
60
40
20
0
0
0.2
0.4
0.6
0.8
1.0
Normalized IDC
1.2
1.4
1.6
1.8
P1 - Initial Inductance, Lo (.1Vrms, 1MHz, 0ADC, 25C)
P2 - Inductance (typically 95% Lo) at Rated IDC.
P3 - Inductance (typically 90% Lo) at Ipk.
Normalized Inductance
US 858 674 8100 • UK 44 1483 401 700 • France 33 3 84 35 04 04 • Singapore 65 287 8998 • Taiwan 886 2 2698 0228 • Hong Kong 852 2788 6588 • http://www.pulseeng.com
29
PC500.B (5/02)