DCX(xxxx)U. Features. Mechanical Data. Ordering Information (Note 3 & 4) SMALL SIGNAL COMPLEMENTARY PRE-BIASED DUAL TRANSISTOR.

DX(xxxx)U SMALL SIGNAL OMPLEMENTARY PRE-BIASED DUAL TRANSISTOR Features Epitaxial Planar Die onstruction Built-In Biasing Resistors Surface Mount Package Suited for Automated Assembly Totally Lead-Free & Fully RoHS compliant (Note ) Halogen and Antimony Free. Green Device (Note 2) Qualified to AE-Q0 Standards for High Reliability Mechanical Data ase: SOT363 ase material: Molded Plastic. Green Molding ompound. lassification Rating 94V-0 Moisture Sensitivity: Level per J-STD-020 Terminals: Matte Tin Finish Weight: 0.006 grams (approximate) Part Number R (NOM) R2 (NOM) DX24EU 22KΩ 22KΩ DX44EU 47KΩ 47KΩ DX4YU 0KΩ 47KΩ DX23JU 2.2KΩ 47KΩ DX4EU 0KΩ 0KΩ DX43EU 4.7KΩ 4.7KΩ Part Number DX43TU DX4TU R Only 4.7KΩ 0KΩ SOT363 Q 6 BQ2 5 EQ2 4 Q 6 BQ2 5 EQ2 4 Q R R 2 Q R R 2 R Q2 R Q2 2 3 EQ BQ Q2 2 3 EQ BQ Q2 Top View R, R2 R Only Device Schematic Ordering Information (Note 3 & 4) Product Grade Marking Reel size (inches) Tape width (mm) Quantity per reel DX24EU-7-F ommercial 7 7 8 3,000 DX24EUQ-7-F Automotive 7 7 8 3,000 DX24EUQ-3-F Automotive 7 3 8 0,000 DX24EUQ-3R-F Automotive 7 3 8 0,000 DX44EU-7-F ommercial 20 7 8 3,000 DX44EU-7R-F ommercial 20 7 8 3,000 DX44EUQ-7-F Automotive 20 7 8 3,000 DX4YU-7-F ommercial 4 7 8 3,000 DX4YUQ-7-F Automotive 4 7 8 3,000 DX4YUQ-3-F Automotive 4 3 8 0,000 DX4YUQ-3R-F Automotive 4 3 8 0,000 DX23JU-7-F ommercial 06 7 8 3,000 DX4EU-7-F ommercial 3 7 8 3,000 DX4EUQ-7-F Automotive 3 7 8 3,000 DX4EUQ-3-F Automotive 3 3 8 0,000 DX43TU-7-F ommercial 07 7 8 3,000 DX43EU-7-F ommercial 08 7 8 3,000 DX4TU-7-F ommercial 2 7 8 3,000 Notes:. No purposely added lead. Fully EU Directive 2002/95/E (RoHS) & 20/65/EU (RoHS 2) compliant. 2. Halogen and Antimony free "Green products are defined as those which contain <900ppm bromine, <900ppm chlorine (<500ppm total Br + l) and <000ppm antimony compounds. 3. -7R and -3R are parts rotated in the pocket tape by 80. For packaging details, go to our website at http://. 4. Products with Q-suffix are automotive grade. Automotive products are electrical and thermal the same as the commercial, except where specified. DX(xxxx)U Document number: DS30347 Rev. 5-2 of 2 March 202

DX(xxxx)U Marking Information XX YM XX = Product Type Marking ode YM = Date ode Marking Y = Year (ex: X = 200) M = Month (ex: 9 = September) Date ode Key Year 200 20 202 203 204 205 206 207 ode X Y Z A B D E Month Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec ode 2 3 4 5 6 7 8 9 O N D Maximum Ratings NPN Section @T A = 25 unless otherwise specified haracteristic Symbol Value Unit Supply Voltage <Pin: (6) to ()> V 50 V DX24EU DX44EU DX4YU -0 to +40-0 to +40-6 to +40 Input Voltage DX23JU -5 to +2 V <Pin: (2) to ()> DX4EU IN -0 to +40 V DX43TU DX43EU DX4TU -5V max -0 to +30-5V max Output urrent DX24EU DX44EU DX4YU DX23JU DX4EU DX43TU DX43EU DX4TU Output urrent I (Max) 00 ma I O 30 30 70 00 50 00 00 00 ma Maximum Ratings PNP Section @T A = 25 unless otherwise specified haracteristic Symbol Value Unit Supply Voltage <Pin: (4) to (3)> V 50 V DX24EU DX44EU DX4YU +0 to -40 +0 to -40 +6 to -40 Input Voltage DX23JU +5 to -2 V <Pin: (5) to (4)> DX4EU IN +0 to -40 V DX43TU DX43EU DX4TU +5V max +0 to -30 +5V max Output urrent DX24EU DX44EU DX4YU DX23JU DX4EU DX43TU DX43EU DX4TU I O -30-30 -70-00 -50-00 -00-00 Output urrent I (Max) -00 ma ma DX(xxxx)U Document number: DS30347 Rev. 5-2 2 of 2 March 202

DX(xxxx)U Thermal haracteristics @T A = 25 unless otherwise specified haracteristic Symbol Value Unit Power Dissipation (Note 5 & 6) P D 00 mw Thermal Resistance, Junction to Ambient Air (Note 5) R θja 625 /W Operating and Storage Temperature Range T J, T STG -55 to +50 Notes: 5. Mounted on FR4 P Board with minimum recommended pad layout 6. 50mW per element must not be exceeded. Electrical haracteristics NPN Section @T A = 25 unless otherwise specified haracteristic Symbol Min Typ Max Unit Test ondition R Only (DX43TU & DX4TU) ollector-base Breakdown Voltage BV BO 50 V I = 50μA ollector-emitter Breakdown Voltage BV EO 50 V I = ma Emitter-Base Breakdown Voltage BV EBO 5 V I E = 50μA ollector utoff urrent I BO 0.5 μa V B = 50V Emitter utoff urrent I EBO 0.5 μa V EB = 4V ollector-emitter Saturation Voltage V E(sat) 0.3 V I /I B = 2.5mA / 0.25mA DX43TU I /I B = ma / 0.mA DX4TU D urrent Transfer Ratio h FE 00 250 600 I = ma, V E = 5V Input Resistor (R ) Tolerance ΔR -30 +30 % Gain-Bandwidth Product f T 250 MHz V E = 0V, I E = -5mA, f = 00MHz R/R2 Only DX24EU 0.5. DX44EU 0.5. DX4YU 0.3 - V DX23JU l(off) 0.5 - V = 5V, I O = 00μA DX4EU 0.5. DX43EU 0.5.6 Input Voltage DX24EU.9 3.0 V V O = 0.3, I O = 5mA DX44EU.9 3.0 V O = 0.3, I O = 2mA DX4YU -.4 V O = 0.3, I O = ma V l(on) DX23JU -. V O = 0.3, I O = 5mA DX4EU.9 3.0 V O = 0.3, I O = 0mA DX43EU.99 3.0 V O = 0.3, I O = 20mA DX24EU I O /I l = 0mA / 0.5mA DX44EU I O /I l = 0mA / 0.5mA Output Voltage DX4YU I O /I l = 5mA / 0.25mA V O(on) 0. 0.3 V DX23JU I O /I l = 5mA / 0.25mA DX4EU I O /I l = 0mA / 0.5mA DX43EU I O /I l = 0mA / 0.5mA DX24EU 0.36 DX44EU 0.8 Input urrent DX4YU 0.88 I l DX23JU 3.6 ma V I = 5V DX4EU 0.88 DX43EU 0.88 Output urrent I O(off) 0.5 μa V = 50V, V I = 0V DX24EU DX24EUQ 56 60 V O = 5V, I O = 5mA V O = 5V, I O = 5mA DX44EU 68 V O = 5V, I O = 5mA D urrent Gain DX4YU 68 V O = 5V, I O = 0mA DX4YUQ G l 80 V O = 5V, I O = 0mA DX23JU 80 V O = 5V, I O = 0mA DX4EU 30 V O = 5V, I O = 5mA DX43EU 50 V O = 5V, I O = 0mA Input Resistor (R ) Tolerance ΔR -30 +30 % Resistance Ratio Tolerance R 2 /R -20 +20 % Gain-Bandwidth Product f T 250 MHz V E = 0V, I E = 5mA, f = 00MHz DX(xxxx)U Document number: DS30347 Rev. 5-2 3 of 2 March 202

DX(xxxx)U Electrical haracteristics PNP Section @T A = 25 unless otherwise specified haracteristic Symbol Min Typ Max Unit Test ondition R Only (DX43TU & DX4TU) ollector-base Breakdown Voltage BV BO -50 V I = -50μA ollector-emitter Breakdown Voltage BV EO -50 V I = -ma Emitter-Base Breakdown Voltage BV EBO -5 V I E = -50μA ollector utoff urrent I BO -0.5 μa V B = -50V Emitter utoff urrent I EBO -0.5 μa V EB = -4V ollector-emitter Saturation Voltage V E(sat) -0.3 V I /I B = 2.5mA / 0.25mA DX43TU I /I B = ma / 0.mA DX4TU D urrent Transfer Ratio h FE 00 250 600 I = -ma, V E = -5V Input Resistor (R ) Tolerance ΔR -30 +30 % Gain-Bandwidth Product f T 250 MHz V E = -0V, I E = 5mA, f = 00MHz R/R2 Only DX24EU -0.5 -. DX44EU -0.5 -. DX4YU -0.3 - V DX23JU l(off) -0.5 - V = -5V, I O = -00μA DX4EU -0.5 -. DX43EU -0.5 -.6 Input Voltage DX24EU -.9-3.0 V V O = -0.3, I O = -5mA DX44EU -.9-3.0 V O = -0.3, I O = -2mA DX4YU - -.4 V O = -0.3, I O = -ma V l(on) DX23JU - -. V O = -0.3, I O = -5mA DX4EU -.9-3.0 V O = -0.3, I O = -0mA DX43EU -2.5-3.0 V O = -0.3, I O = -20mA DX24EU I O /I l = -0mA / -0.5mA DX44EU I O /I l = -0mA / -0.5mA Output Voltage DX4YU I O /I l = -5mA / -0.25mA V O(on) -0. -0.3 V DX23JU I O /I l = -5mA / -0.25mA DX4EU I O /I l = -0mA / -0.5mA DX43EU I O /I l = -0mA / -0.5mA DX24EU -0.36 DX44EU -0.8 Input urrent DX4YU -0.88 I l DX23JU -3.6 ma V I = -5V DX4EU -0.88 DX43EU -0.88 Output urrent I O(off) -0.5 μa V = 50V, V I = 0V DX24EU DX24EUQ 56 60 V O = -5V, I O = -5mA V O = -5V, I O = -5mA DX44EU 68 V O = -5V, I O = -5mA D urrent Gain DX4YU 68 V O = -5V, I O = -0mA DX4YUQ G l 80 V O = -5V, I O = -0mA DX23JU 80 V O = -5V, I O = -0mA DX4EU 30 V O = -5V, I O = -5mA DX43EU 40 V O = -5V, I O = -0mA Input Resistor (R ) Tolerance ΔR -30 +30 % Resistance Ratio Tolerance R 2 /R -20 +20 % Gain-Bandwidth Product f T 250 MHz V E = -0V, I E = -5mA, f = 00MHz DX(xxxx)U Document number: DS30347 Rev. 5-2 4 of 2 March 202

DX(xxxx)U Typical urves Total Device 250 P D, POWER DISSIPATION (mw) 200 50 00 50 0 0 50 25 50 T A, AMBIENT TEMPERATURE ( ) Fig. Power Derating urve Typical urves DX23JU I /I = 0 B PNP Section,000 V E(SAT), OLLETOR-EMITTER 0. 0.0 25 75-25 h FE, D URRENT GAIN 00 0.00 0 0 20 30 40 50 Fig. 2 Typical VE(SAT) vs. I 0 0 00 Fig. 3 Typical D urrent Gain OB, APAITANE (pf) 2 0 8 6 4 2 I E = 0mA f = MHz I, OLLETOR URRENT (ma) 00 0 0. 0.0 T = 75 A 0 0 5 0 5 20 25 30 V R, REVERSE BIAS VOLTAGE (V) Fig. 4 Typical Output apacitance 0.00 0 2 3 4 5 6 7 8 9 0 V IN, INPUT VOLTAGE (V) Fig. 5 Typical ollector urrent vs. Input Voltage DX(xxxx)U Document number: DS30347 Rev. 5-2 5 of 2 March 202

DX(xxxx)U Typical urves DX23JU PNP Section (cont.) 0 V IN, INPUT VOLTAGE (V) 0. 0 0 20 30 40 50 Fig. 6 Typical Input Voltage vs. ollector urrent Typical urves DX23JU NPN Section I /I = 0 B,000 V = 0V E V E(SAT), OLLETOR-EMITTER 0. 0.0 T A = 25 T A = 75 T A = -25 h FE, D URRENT GAIN 00 T A = 75 0.00 0 0 20 30 40 50 Fig. 7 Typical VE(SAT) vs. I 0 0 00 Fig. 8 Typical D urrent Gain OB, APAITANE (pf) 4 3 2 I E = 0mA f = MHz I, OLLETOR URRENT (ma) 00 0 0. 0.0 T = -25 A T = 75 A T = 25 A V = 5V O 0 0 5 0 5 20 25 30 V R, REVERSE BIAS VOLTAGE (V) Fig. 9 Typical Output apacitance DX(xxxx)U Document number: DS30347 Rev. 5-2 6 of 2 0.00 0 2 3 4 5 6 7 8 9 0 V IN, INPUT VOLTAGE (V) Fig. 0 Typical ollector urrent vs. Input Voltage March 202

DX(xxxx)U Typical urves DX23JU NPN Section (cont.) 0 V IN, INPUT VOLTAGE (V) 0. 0 0 20 30 40 50 Fig. Typical Input Voltage vs. ollector urrent Typical urves DX43EU PNP Section I, OLLETOR URRENT (A) I = 3mA b I = 2.5mA b I = 3.5mA b I = 2mA b I = 4mA b I =.5mA b I = 4.5mA b I = ma b I = 0.5mA b h FE, D URRENT GAIN V E, OLLETOR EMITTER VOLTAGE (V) Fig. 2 Typical V E vs. I Fig. 3 Typical D urrent Gain I /I = 0 B V E(SAT), OLLETOR-EMITTER V BE, BASE-EMITTER VOLTAGE (V) DX(xxxx)U Document number: DS30347 Rev. 5-2 Fig. 4 Typical V E(SAT) vs. I 7 of 2 Fig. 5 Typical V BE vs. I March 202

DX(xxxx)U Typical urves DX43EU PNP Section (cont.) V BE(SAT), BASE-EMITTER V I(ON), INPUT VOLTAGE (V) Fig. 6 Typical V BE(SAT) vs. I Typical urves DX43EU NPN Section I, OUTPUT URRENT (ma) Fig. 7 Typical V I(ON) vs. I I, OLLETOR URRENT (A) h FE, D URRENT GAIN V E, OLLETOR EMITTER VOLTAGE (V) Fig. 8 Typical V E vs. I Fig. 9 Typical D urrent Gain V E(SAT), OLLETOR-EMITTER V BE, BASE-EMITTER VOLTAGE (V) DX(xxxx)U Document number: DS30347 Rev. 5-2 Fig. 20 Typical V E(SAT) vs. I 8 of 2 Fig. 2 Typical V BE vs. I March 202

DX(xxxx)U Typical urves DX43EU NPN Section (cont.) V BE(SAT), BASE-EMITTER V I(ON), INPUT VOLTAGE (V) Fig. 22 Typical V BE(SAT) vs. I Typical urves DX4TU PNP Section I /I = 0 B,000 I, OUTPUT URRENT (ma) Fig. 23 Typical V I(ON) vs. I V E(SAT), OLLETOR-EMITTER 0. 0.0 T A = 25 T A = 75 T A = -25 h FE, D URRENT GAIN 00 0 0.00 0 0 20 30 40 50 Fig. 24 Typical VE(SAT) vs. I 0 00 Fig. 25 Typical D urrent Gain 4 00 OB, APAITANE (pf) 3 2 I E = 0mA f = MHz I, OLLETOR URRENT (ma) 0 0. 0.0 T = -25 A 0 0 5 0 5 20 25 30 V R, REVERSE BIAS VOLTAGE (V) Fig. 26 Typical Output apacitance DX(xxxx)U Document number: DS30347 Rev. 5-2 9 of 2 0.00 0 2 3 4 5 6 7 8 9 0 V IN, INPUT VOLTAGE (V) Fig. 27 Typical ollector urrent vs. Input Voltage March 202

DX(xxxx)U Typical urves DX4TU PNP Section (cont.) 0 V IN, INPUT VOLTAGE (V) 0. 0 0 20 30 40 50 Fig. 28 Typical Input Voltage vs. ollector urrent Typical urves DX4TU NPN Section I /I = 0 B,000 V E(SAT), OLLETOR-EMITTER 0. 0.0 T A = 25 T A = 75 T A = -25 h FE, D URRENT GAIN 00 0 0.00 0 0 20 30 40 50 Fig. 29 Typical VE(SAT) vs. I 0 00 Fig. 30 Typical D urrent Gain OB, APAITANE (pf) 4 3 2 I E = 0mA f = MHz I, OLLETOR URRENT (ma) 00 0 0. 0.0 T = 75 A T =-25 A T = 25 A 0 0 5 0 5 20 25 30 V R, REVERSE BIAS VOLTAGE (V) Fig. 3 Typical Output apacitance DX(xxxx)U Document number: DS30347 Rev. 5-2 0 of 2 0.00 0 2 3 4 5 6 7 8 9 0 V IN, INPUT VOLTAGE (V) Fig. 32 Typical ollector urrent vs. Input Voltage March 202

DX(xxxx)U Typical urves DX4TU NPN Section (cont.) 0 V IN, INPUT VOLTAGE (V) 0. 0 0 20 30 40 50 Fig. 33 Typical Input Voltage vs. ollector urrent Package Outline Dimensions K J A H D F B L M SOT363 Dim Min Max A 0.0 0.30 B.5.35 2.00 2.20 D 0.65 Typ F 0.40 0.45 H.80 2.20 J 0 0.0 K 0.90.00 L 0.25 0.40 M 0.0 0.22 α 0 8 All Dimensions in mm Suggested Pad Layout 2 2 Z G Y Dimensions Value (in mm) Z 2.5 G.3 X 0.42 Y 0.6.9 2 0.65 X DX(xxxx)U Document number: DS30347 Rev. 5-2 of 2 March 202

DX(xxxx)U IMPORTANT NOTIE DIODES INORPORATED MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARDS TO THIS DOUMENT, INLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERHANTABILITY AND FITNESS FOR A PARTIULAR PURPOSE (AND THEIR EQUIVALENTS UNDER THE LAWS OF ANY JURISDITION). Diodes Incorporated and its subsidiaries reserve the right to make modifications, enhancements, improvements, corrections or other changes without further notice to this document and any product described herein. Diodes Incorporated does not assume any liability arising out of the application or use of this document or any product described herein; neither does Diodes Incorporated convey any license under its patent or trademark rights, nor the rights of others. Any ustomer or user of this document or products described herein in such applications shall assume all risks of such use and will agree to hold Diodes Incorporated and all the companies whose products are represented on Diodes Incorporated website, harmless against all damages. Diodes Incorporated does not warrant or accept any liability whatsoever in respect of any products purchased through unauthorized sales channel. Should ustomers purchase or use Diodes Incorporated products for any unintended or unauthorized application, ustomers shall indemnify and hold Diodes Incorporated and its representatives harmless against all claims, damages, expenses, and attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized application. Products described herein may be covered by one or more United States, international or foreign patents pending. Product names and markings noted herein may also be covered by one or more United States, international or foreign trademarks. LIFE SUPPORT Diodes Incorporated products are specifically not authorized for use as critical components in life support devices or systems without the express written approval of the hief Executive Officer of Diodes Incorporated. As used herein: A. Life support devices or systems are devices or systems which:. are intended to implant into the body, or 2. support or sustain life and whose failure to perform when properly used in accordance with instructions for use provided in the labeling can be reasonably expected to result in significant injury to the user. B. A critical component is any component in a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or to affect its safety or effectiveness. ustomers represent that they have all necessary expertise in the safety and regulatory ramifications of their life support devices or systems, and acknowledge and agree that they are solely responsible for all legal, regulatory and safety-related requirements concerning their products and any use of Diodes Incorporated products in such safety-critical, life support devices or systems, notwithstanding any devices- or systems-related information or support that may be provided by Diodes Incorporated. Further, ustomers must fully indemnify Diodes Incorporated and its representatives against any damages arising out of the use of Diodes Incorporated products in such safety-critical, life support devices or systems. opyright 202, Diodes Incorporated DX(xxxx)U Document number: DS30347 Rev. 5-2 2 of 2 March 202