AND9083/D MOSFET Gate-Charge Origin and its Applications Introduction www.onsemi.com APPLICATION NOTE 32 V + ID 0 à 10 V + − VDS − VGS 10 9 8 ID = 30 A, VDS = 5 V 30 A 7 6 5 ID = 5 A, VDS = 30 V 4 Figure 2. Inductive Switching 3 2 QSW 35 VGS, GATE−TO−SOURCE VOLTAGE (V) 10 1 0 0 5 10 15 20 25 30 35 QG, TOTAL GATE CHARGE (nC) Figure 1. NTD5805N Gate-to-Source Voltage vs. Total Charge Inductive Switching In switch-mode power supplies, MOSFETs switch inductive loads. Figure 2 shows a basic buck circuit with high side MOSFET turn on transition. Before the high side MOSFET is turned on, inductor current is flowing through the low side MOSFET’s body diode (VBD). The turn-on transition is broken down into three regions (Figure 3). These regions will be individually explained. Figure 4 shows the transition through these regions in terms of output characteristics. Gate charge can be derived from the non-linear capacitance curves, which are fully characterized at a range of VDS (VGS = 0 V) and VGS (VDS = 0 V) as shown in Figure 5. © Semiconductor Components Industries, LLC, 2016 February, 2016 − Rev. 2 9 8 ID VDS 30 QG 7 6 20 5 VGP 15 4 3 2 25 10 VTH A 1 0 B C 5 0 0 ID, DRAIN CURRENT (A), VDS, DRAIN−SOURCE VOLTAGE (V) VGS, GATE−TO−SOURCE VOLTAGE (V) Engineers often estimate switching time based on total drive resistances and gate charge or capacitance. Since capacitance is non-linear, gate charge is an easier parameter for estimating switching behavior. However, the MOSFET switching time estimated from datasheet parameters does not normally match what the oscilloscope shows. This is due to differences between the parameters taken from the datasheet and the application conditions. For example, in Figure 1 the gate charge of NTD5805N was characterized at two different conditions and results varied greatly. If datasheet values are characterized at conditions different from the user, the differences will introduce error in the estimation. This article will explain how to better estimate gate charge from datasheets and their applications. For simplicity in this article, power MOSFET NTD5805N’s datasheet [1] is used with circuit conditions of 32 V and 30 A. 10 20 30 QG, TOTAL GATE CHARGE (nC) Figure 3. Gate-to-Source Voltage and Switching vs. Total Charge 1 Publication Order Number: AND9083/D AND9083/D VGS = 5.5 V − 10 V 100 3000 VGS = 5.2 V 80 2500 C, CAPACITANCE (pF) ID, DRAIN CURRENT (A) 90 5V 70 60 4.5 V 50 40 C 4.2 V VGP B 30 4V 20 1 2 3 30 1000 A Coss B 3.5 V 0 C 1500 500 A 10 0 Ciss 2000 Crss 0 10 40 5 0 VGS VDS, DRAIN−TO−SOURCE VOLTAGE (V) 5 10 15 20 25 30 35 40 VDS GATE−TO−SOURCE OR DRAIN−TO−SOURCE VOLTAGE (V) Figure 4. On-Region Characteristics for Different Gate-to-Source Voltages Figure 5. Capacitance Variation Region A: MOSFET QGS Region C: MOSFET Remaining Total Gate Charge This is the region where gate-to-source voltage (VGS) rises from 0 V to its plateau voltage (VGP). When the gate rises from 0 V to its threshold voltage (VTH), the MOSFET is still off with no drain current (ID) flow and drain-to-source voltage (VDS) remains clamped. Once gate voltage reaches VTH, the MOSFET starts conducting and ID rises. Its VDS is still clamped to VDD + VBD until all inductor current is being supplied by the MOSFET. In this region, gate current is used to charge the input capacitance (Ciss) with its VDS being clamped. Since voltage across gate-to-drain changes from VDD to VDD – VGP, charge is stored from the input capacitance curve at that range. It can be approximated by Equation 1. This is the region where the MOSFET enters into ohmic mode operation as seen in the ID−VDS curve (Figure 4). VGS rises from VGP to driver supply voltage (VGDR). Both ID and VDS remain relatively constant. ID is still clamped by the inductor current. As VGS increases, the channel (VDS = I * RDS(ON)) continue to be more enhanced and VDS dropped slightly. The charge needed is shown as region C in Figure 5 and can be calculated by Equation 3. Q GS ^ ŕ V DD V DD * V GP Ciss(V DS) @ dV QC ^ DD * V GP GP GP Ciss(V GS) @ dV (eq. 3) It was explained above how different sections of gate charge are formed. Circuit conditions determine gate charge boundaries between regions A, B and C (Figure 6). The range is set by VDD and VGDR. VGP can be found from ID−VDS curves at inductor current (ID) and supply voltage (VDD). With these three voltages found, gate charge equals to area under those capacitance regions. An example is shown in Table 1 employing methodology described the same circuit conditions as characterization data in Figure 1 using only simple estimations. Total gate charge (QGTOT) is the total amount charge stored by the MOSFET on its gate up to the driver voltage. Switching gate charge (QSW) is the amount charge needed to complete ID and VDS transitions. (eq. 1) This is the region where VGS is held at VGP and remains flat. ID clamps to inductor current and VDS clamping effect is gone, MOSFET’s VDS starts to drop. It can be seen from ID−VDS curve (Figure 4) that VGS remains relatively constant at fixed ID with varying VDS. This is the origin of the flat plateau seen on the gate charge curve. During this region, the gate current is used to charge the reverse transfer capacitance (Crss). VDS is decreasing from VDD + VBD to ID * RDS(ON). Thus the voltage across Crss (gate-to-drain capacitance) changes from {(VDD + VBD) − VGP} to {(ID * RDS(ON)) − VGP}. The polarity of voltage is reversed. Charge (Equation 2) needed for this transition is shown as the area under region B capacitance curve of Figure 5. ŕ V0 V )ŕ 0 GDR Getting the Gate Charge for Different Conditions Region B: MOSFET QGD Q GD ^ ŕ VV Crss(V DS) @ dV ) (eq. 2) Crss(V GS) @ dV www.onsemi.com 2 AND9083/D GATE−TO−SOURCE OR DRAIN−TO−SOURCE VOLTAGE (V) VGS VDS 3000 C, CAPACITANCE (pF) 2500 2000 C 1500 A 1000 500 B 0 VGDR VGP(ID) VDD − VGP(ID) VDD Figure 6. Circuit Parameters Effects Table 1. ESTIMATION OF GATE CHARGE BASED ON METHOD DESCRIBED Parameters VDD = 30 V, ID = 5 A VDD = 5 V, ID = 30 A Refer to VGP 3.6 V 4.2 V ID – VDS Curve Region A − Charge 3.6 V * 1.7 nF ≈ 6.1 nC 4.2 V * 1.9 nC ≈ 8.0 nC Region B − Charge (30 V – 3.6 V) * 0.2 nF + 3.6 V * 1.1 nF ≈ 9.2 nC (5 V – 4.2 V) * 0.4 nF + 3.6 V * 1.1 nF ≈ 4.9 nC Region C − Charge (10 V – 3.6 V) * 2.7 nF ≈ 18 nC (10 V – 4.2 V) * 2.7 nF ≈ 15.95 nC QGTOT 33 nC 29 nC Capacitance Curve Sum A, B & C VTH 2.7 V 2.7 V Datasheet Value QSW (3.6 V – 2.7 V) / 3.6 V * 6.1 nF + 9.2 nC ≈ 11 nC (4.2 V – 2.7 V) / 4.2 V * 8.0 nF + 4.9 nC ≈ 7.8 nC QA(after VTH) + QB 32 V Resistive Switching LED and heating coil are examples of resistive switching. The main difference between inductive and resistive switching is that there is no clamping of drain current involved. Before reaching its threshold voltage, the FET is off. When the MOSFET starts to turn-on in the saturation region, VDS is dependent on resistive load and voltage supply. Once the FET is in ohmic mode, the MOSFET and the load become a simple resistor divider. There is no flat plateau region as both VDS and ID are changing resulting in increasing VGS (Figure 9 region E). Fortunately, QSW and QGTOT are unchanged from inductive switching. 32 / 30 W + 0 à 10 V + − ID VGS Figure 7. Resistive Switching www.onsemi.com 3 VDS − AND9083/D QSW 35 ID VDS 8 30 25 7 6 20 5 4 15 3 10 2 VTH F E 1 0 5 D 0 0 10 20 100 90 ID, DRAIN CURRENT (A) VGS, GATE−TO−SOURCE VOLTAGE (V) 9 ID, DRAIN CURRENT (A), VDS, DRAIN−SOURCE VOLTAGE (V) 10 80 70 60 50 40 F 30 E 20 10 0 30 D 0 QG, TOTAL GATE CHARGE (nC) 10 20 30 40 VDS, DRAIN−TO−SOURCE VOLTAGE (V) Figure 8. Gate-to-Source Voltage and Switching vs. Total Charge (Resistive Switching) Figure 9. On-Region Characteristics for Different Gate-to-Source Voltages Gate Charge Applications charge (QSW) is the amount of current the gate driver needed to supply to complete the switching transitions of drain voltage and current. Gate charge loss (PQG) is power dissipated due to charging and discharging of the gate. One important aspect of MOSFET applications is the power losses. There are several power loss components. Conduction loss is power dissipated in the resistive element (RDSON) of the channel. Switching loss (PSW) is power dissipated in switching current and voltage. Switching gate P QG + Q GTOT@VGDR @ V GDR @ F SW (eq. 4) Q SW + Q GS(afterVth) ) Q GD (eq. 5) T SW(ON) + Q SWń ǒ Ǔ ǒ Ǔ V GDR * V GP V GP , T SW(OFF) + Q SWń R DR ) R G R DR ) R G (eq. 6) P SW(inductive) + 0.5 @ V DD @ I D @ ǒT SW(ON) ) T SW(OFF)Ǔ @ F SW (eq. 7) P SW(resistive) + 0.25 @ V DD @ I D @ ǒT SW(ON) ) T SW(OFF)Ǔ @ F SW (eq. 8) inductive switching or short-circuit performance can also be evaluated. Derivations above do not apply to zero voltage switching applications. For example in synchronous rectification, MOSFET has a negative diode voltage drop across VDS (body diode conduction) before it is turned on. They can still be derived from the capacitances (VGS side) and ID−VDS curve using the same idea. 40 QGTOT@10 VGS GATE CHARGE (nC) 35 Conclusion With different circuit conditions, it has been shown how datasheet gate charge parameters changes. Only simple mathematics is needed in getting the right gate charge. The origins of gate charge are analytically explained. Through understanding of MOSFET gate charge, more accurate estimations can be made in designing for different circuit conditions (Figure 10). Trade offs are evaluated in selecting gate drive schemes. A lower gate drive voltage would save some energy but must be balanced between higher on-resistance. Using methods described by D. Lee in [2], extreme operating conditions like repetitive unclamped 30 25 ID = 1 A ID = 50 A 20 15 QSW 10 5 0 0 10 20 30 VDS, DRAIN−TO−SOURCE VOLTAGE (V) Figure 10. NTD5805N Gate Charge at Various Conditions www.onsemi.com 4 40 AND9083/D APPENDIX A: ESTIMATION WITHOUT CAPACITANCE-vs-VGS CURVE 3000 C, CAPACITANCE (pF) 2500 Ciss 2000 1500 1000 Coss 500 0 10 5 Vgs Crss 0 5 10 Vds 15 20 25 30 35 40 GATE−TO−SOURCE OR DRAIN−TO−SOURCE VOLTAGE (V) Figure 11. NTD5805N Capacitance Curves Since most of the MOSFETs datasheet are without Capacitance-vs-VGS curve (shaded part of the Figure 11), estimation will have to be made based on the available information. The missing Capacitance-vs-VGS curves will concern region B and region C. Figure 12. Circuit Parameters Effects For region C, we can estimate the gate charge after VGP(ID) due to its constant capacitance. For region B, we can assume VGP(ID) are relative constant in modern trench MOSFET devices. Due to the high trench density (high transconductance), a large change in drain current, ID, only resulted in small increase in gate plateau voltage, VGP(ID). www.onsemi.com 5 AND9083/D For example using 40 V NTMFS5C442NL, 220 VDS = 3 V 160 200 3.8 V 180 160 ID, DRAIN CURRENT (A) ID, DRAIN CURRENT (A) 180 4.0 V 10 V to 4.5 V 3.6 V 140 3.4 V 120 3.2 V 100 80 3.0 V 60 2.8 V 40 140 120 100 80 TJ = 25°C 60 40 TJ = 125°C 20 20 0 TJ = −55°C 0 0 0.5 1.0 1.5 2.0 2.5 3.0 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 VDS, DRAIN−TO−SOURCE VOLTAGE (V) VGS, GATE−TO−SOURCE VOLTAGE (V) Figure A. On-Region Characteristics Figure B. Transfer Characteristics 4.0 Figure 13. NTMFS5C442NL Datasheet Curves for every 15 A increase or decrease in drain current. We can conclude that VGP for modern trench MOSFET devices are relative constant due to high transconductance. From Figure A and B of NTMFS5C442NL, we can see that when Gate-to-Source voltage, VGS, changed from 3.0 V to 3.2 V the drain current, ID, increase by 30 A. Therefore, it implied gate plateau VGP change by approximately 0.1 V Table 2. NTMFS5C442NL DATASHEET PARAMETERS Parameter Symbol Test Condition Min Typ Max Total Gate Charge QG(TOT) VGS = 4.5 V, VDS = 32 V, ID = 50 A − 23 − Total Gate Charge QG(TOT) VGS = 10 V, VDS = 32 V, ID = 50 A − 50 − Threshold Gate Charge QG(TH) − 5.0 − − 9.8 − − 6.7 − − 3.1 − Gate-to-Source Charge QGS Gate-to-Drain Charge QGD Plateau Voltage VGP VGS = 4.5 V, VDS = 32 V, ID = 50 A Figure 14. NTMFS5C442NL Capacitance Curves with Datasheet Test Conditions www.onsemi.com 6 Unit nC V AND9083/D Region A = QGS = 9.8 nC (estimated from curve = 3.1 V * 3100 pF = 9.6 nC) Region B = QGD = 6.7 nC Region C = QGTOT – QGS – QGD = 33.5 nC Calculate for Different Test Conditions For example at VGS = 6 V, VDS = 20 V, ID = 20 A: Figure 15. NTMFS5C442NL Capacitance Curves with New Test Conditions Region A = 3.1 V * 3100 pF = 9.6 nC Region B = 6.7 nC – (12 V * 100 pF) = 5.5 nC Region C = 33.5 nC / (10 V – 3.1 V) * (6 V – 3.1 V) = 14.1 nC Figure 16. Graphic Representation of Change in Above NTMFS5C442NL Estimation www.onsemi.com 7 AND9083/D Figure 17. Gate Charge Comparison between Test Conditions The change in gate change can be seen in Figure 16 with new test condition in shaded regions. REFERENCES [1] ON Semiconductor, “Power MOSFET 40 V NTD5805N Datasheet”, http://www.onsemi.com/pub_link/Collateral/ NTD5805N−D.PDF [2] ON Semiconductor, “MOSFET Transient Junction Temperature Under Repetitive UIS/Short-Circuit Conditions”, http://www.onsemi.com/pub_link/Collateral/ AND9042−D.PDF [3] ON Semiconductor, “Power MOSFET 40 V NTMFS5C442NL Datasheet”, http://www.onsemi.com/pub_link/Collateral/ NTMFS5C442NL-D.PDF ON Semiconductor and the are registered trademarks of Semiconductor Components Industries, LLC (SCILLC) or its subsidiaries in the United States and/or other countries. SCILLC owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent−Marking.pdf. SCILLC reserves the right to make changes without further notice to any products herein. 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