STPS2045CR ,POWER SCHOTTKY RECTIFIERapplications.TO-220FPAB D PAKSTPS2045CFP STPS2045CGTable 2: Order CodesPart Number MarkingSTPS2045C ..
STPS2045CT ,POWER SCHOTTKY RECTIFIERSTPS2045CT/CF/CG/CFP®POWER SCHOTTKY RECTIFIERMAIN PRODUCT CHARACTERISTICSI 2x10AF(AV) A1KV 45 VRRMA ..
STPS2045CT.. ,POWER SCHOTTKY RECTIFIERapplications.ABSOLUTE RATINGS (limiting values, per diode)Symbol Parameter Value UnitV Repetitive p ..
STPS2060CT ,POWER SCHOTTKY RECTIFIERSTPS2060CT®POWER SCHOTTKY RECTIFIERMAIN PRODUCT CHARACTERISTICSI 2x10AF(AV)A1V 60 VRRMKV (max) 0.58 ..
STPS20H100 ,HIGH VOLTAGE POWER SCHOTTKY RECTIFIERFEATURES AND BENEFITSn NEGLIGIBLE SWITCHING LOSSESn HIGH JUNCTION TEMPERATURE CAPABILITYA2A2KKn GOO ..
STPS20H100CFP ,HIGH VOLTAGE POWER SCHOTTKY RECTIFIERSTPS20H100CT/CF/CG/CR/CFP®HIGH VOLTAGE POWER SCHOTTKY RECTIFIERMAIN PRODUCT CHARACTERISTICSI 2x10A ..
T1108NL , TELECOMMUNICATIONS PRODUCTS
T1111NL , TELECOMMUNICATIONS PRODUCTS
T11-12 , TELECOMMUNICATIONS PRODUCTS
T11-12 , TELECOMMUNICATIONS PRODUCTS
T1113 , TELECOMMUNICATIONS PRODUCTS
T1113NL , TELECOMMUNICATIONS PRODUCTS
STPS2045CR
POWER SCHOTTKY RECTIFIER
1/8
Table 1: Main Product Characteristics
STPS2045CPOWER SCHOTTKY RECTIFIER
REV. 5
November 2004
FEATURES AND BENEFITS Very small conduction losses Negligible switching losses Extremely fast switching Insulated package: TO-220FPAB
Insulating voltage = 2000V DC
Capacitance = 12 pF Avalanche rated
DESCRIPTIONDual center tap Schottky rectifier suited for
SwitchMode Power Supply and high frequency
DC to DC converters.
Packaged either in TO-220AB, TO-220FPAB,2 PAK, or D2 PAK, this device is especially
intended for use in low voltage, high frequency
inverters, free wheeling and polarity protection
applications.
Table 2: Order Codes
STPS2045C
Table 3: Absolute Ratings (limiting values, per diode)
Table 4: Thermal Resistance Parameters
Table 5: Static Electrical Characteristics (per diode)Pulse test: * tp = 380 µs, δ < 2%
To evaluate the conduction losses use the following equation: P = 0.42 x IF(AV) + 0.015 IF2 (RMS)
* : thermal runaway condition for a diode on its own heatsink
When the diodes 1 and 2 are used simultaneously:
Tj(diode 1) = P(diode 1) x Rth(j-c)(per diode) + P(diode 2) x Rth(c)
dPtot
dTj--------------- 1
Rthja–()--------------------------<
STPS2045C3/8
Figure 1: Average forward power dissipation
versus average forward current (per diode)
Figure 2: Average forward current versus
ambient temperature (δ = 0.5, per diode)
Figure 3: Normalized avalanche power
derating versus pulse duration
Figure 4: Normalized avalanche power
derating versus junction temperature
Figure 5: Non repetitive surge peak forward
current versus overload duration (maximum
values, per diode) (TO-220AB, D2 PAK, I2 PAK)
Figure 6: Non repetitive surge peak forward
current versus overload duration (maximum
values, per diode) (TO-220FPAB)
STPS2045C
Figure 7: Relative variation of thermal
impedance junction to ambient versus pulse
duration (TO-220AB, D2 PAK, I2 PAK)
Figure 8: Relative variation of thermal
impedance junction to ambient versus pulse
duration (TO-220FPAB)
Figure 9: Reverse leakage current versus
reverse voltage applied (typical values, per
diode)
Figure 10: Junction capacitance versus
reverse voltage applied (typical values, per
diode)
Figure 11: Forward voltage drop versus
forward current (maximum values, per diode)
Figure 12: Thermal resistance junction to
ambient versus copper surface under tab
(Epoxy printed circuit board, copper
thickness: 35µm) (D2 PAK)
STPS2045C5/8
Figure 13: D2 PAK Package Mechanical Data
Figure 14: Foot Print Dimensions (in millimeters)
STPS2045C
Figure 15: TO-220AB Package Mechanical Data
Figure 16: I2 PAK Package Mechanical Data