vb.net barcode reader source code 1N4001 1N4007 Features Low forward voltage drop High surge current capability in Software

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1N4001 1N4007 Features Low forward voltage drop High surge current capability
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This table summarizes the limitations of the device For example, in the rst column one can nd the maximum allowable average current (1 A), and the maximum surge current, that is the maximum short-time burst current the diode can sustain without being destroyed Also mentioned are the power rating and operating temperatures Note that in the entry for the total device power dissipation, derating information is also given Derating implies that the device power dissipation will change as a function of temperature, in this case at the rate of 20 mW/ C For example, if we expect to operate the diode at a temperature of 100 C, we would calculate a derated power of: P = 25 W (75 C 002 mW/ C) = 10 W Thus, the diode operated at a higher temperature can dissipate only 1 W
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Absolute Maximum Ratings Symbol I0 it (surge) Parameter
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T = 25 C unless otherwise noted
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Units A
Average Recti ed Current 375 lead length @ TA = 75 C Peak Forward Surge Current 83 ms single half-sine-wave Superimposed on rated load (JEDEC method) Total Device Dissipation Derate above 25 C Thermal Resistance, Junction to Ambient Storage Temperature Range Operating Junction Temperature
PD R8J A Tstg TJ
25 20 50 55 to +175 55 to +150
W mW/ C
C/W C C
These ratings are limiting values above which the serviceability of any semiconductor device may be impaired
ELECTRICAL CHARACTERISTICS:
The section on electrical characteristics summarizes some of the important voltage and current speci cations of the diode For example, the maximum DC reverse voltage is listed for each diode in the 1N400X family Similarly, you will nd information on the maximum forward voltage, reverse current, and typical junction capacitance
Electrical Characteristics Parameter 4001 Peak Repetitive Reverse Voltage Maximum RMS Voltage DC Reverse Voltage (Rated VR ) 50 35 50 4002 100 70 100 4003 200 140 200
T = 25 C unless otherwise noted
Device 4004 400 280 400 4005 600 420 600 4006 800 560 800 4007 1000 700 1000
Units
V V V
Maximum Reverse Current @ rated VR TA = 25 TA = 100 Maximum Forward Voltage @ 10 A Maximum Full Load Reverse Current, Full Cycle TA = 75 Typical Junction Capacitance VR = 40 V, f = 10 MHz
50 500 11 30
A A V A
TYPICAL CHARACTERISTIC CURVES:
Device data sheets always include characteristic curves that may be useful to a designer In this example, we include the forward-current derating curve, in which the maximum forward current is derated as a function of temperature To illustrate this curve, we point out that at a temperature of 100 C the maximum diode current
Part II
Electronics
(Concluded)
is around 065 A (down from 1 A) A second curve is related to the diode forward current versus forward voltage (note that this curve was obtained for a very particular type of input, consisting of a pulse of width equal to 300 s and 2 percent duty cycle
16 Forward Current (A) 14 12 1
Forward Current Derating Curve Forward Current (A)
Single Phase Half Wave 80HZ Resistive or 04 Inductive Load 02 375" 90 mm Lead Lengths 0 0 20 40 60 80 100 120 140 160 180 Ambient Temperature ( C) 08 06
20 10 4 2 1 04 02 01 004 002 001 06
Forward Characteristics
TJ = 25 C Pulse width = 500 S 2% Duty Cycle 08 1 12 Forward Voltage (V) 14
EXAMPLE 85 Using Load Line Analysis and Diode Curves to Determine the Operating Point of a Diode
Problem
Determine the operating point of the 1N941 diode in the circuit of Figure 831 and compute the total power output of the 12-V battery
R1 R3 iD Vs R2 D1 + vD _
Solution
Known Quantities: VS = 12 V; R1 = 50
; R2 = 10
; R3 = 20
; R4 = 20
Find: The diode operating voltage and current and the power supplied by the battery Assumptions: Use the diode nonlinear model, as described by its i-v curve (Figure 832) Analysis: We rst compute the Th venin equivalent representation of the circuit of e Figure 831 to reduce it to prepare the circuit for load-line analysis (see Figures 829 and 830)
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