An Analytical Model of Dynamic Power Losses in eGaN HEMT Power Devices
Abstract
:1. Introduction
2. Background and Methodology
2.1. Traditional Power Loss Model
2.2. Experimental Circuit and Method
2.3. Qualitative Method Used to Discover the Channel Behavior
3. Extraction of the Dynamic Rdson
4. Discussion on the Effect of the Drain Current using a Double-Mode Test Technique
5. Investigation of the Real Channel Current
6. Modeling of Switching Power Losses
6.1. Stage 1 (S1)—Off-State with a High Vds
6.2. Stage 2 (S2)—On-State in Saturation Region
6.3. Stage 3 (S3)—Turn-on Transition
- 1.
- In the t1–t2 time interval, Idrain increases almost linearly from 0 to the Ista at t2, which is similar to a Si-based MOSFET [13,34], while Vdrain decreases slightly from Vds to Vr due to the result of the parasitic inductance voltage drop caused by a high di/dt in the circuit. At t2, the current of the freewheeling diode D1 decreases to zero. In this time interval, the gate voltage of the device slightly exceeds Vth, meaning that the device is operating in a linear region. Meanwhile, the trapping effect of a high electric field will also lead to a large dynamic Rdson in the linear region (Rturn_on_cr), which is similar to that in the on-state, as well as an extra gate lag. Thus, the coefficients of the dynamic Rdson should be the same as those in Figure 4. Assuming that the heatsink is large enough and the self-heating effect is ignored, the t1–t2 time interval, Vr, and the power losses in this time interval (Pturn_on_cr) can be written as follows:
- 2.
- In the t2–t3 time interval, the HEMT device takes over the total inductive load current, and Vds decreases to a boundary voltage of (Vmr − Vth) at t3 due to the discharging of Coss. The stray inductors in series around the circuit are resonant with Coss and the stray capacitors (Cstray) in this time interval. The current path through the device is illustrated in Figure 5b. It is assumed that Vgs and ista remain unchanged, and the reverse recovery of the D1 is zero. In addition, the current in this time interval is usually large enough; hence, the charging time of Coss can be ignored. Moreover, voltage-dependent Coss is not suitable for the calculation of power losses in this time interval because Vdrain is always changing. Therefore, Qgd is used to replace Coss, and the time interval of t2–t3 can then be written as follows:where is the average channel current during the t2–t3 time interval.
- 3.
- During the t3–t4 time interval, the HEMT device operates in an ohmic conducting state. Then, Vdrain continues to decrease until it reaches a low on-voltage (Von) from (Vmr − Vth). Assuming that ista and the Miller voltage Vmr do not change, the t3–t4 time interval, Von_r, and the power losses in this time interval (Pturn_on_mr) can be written as follows [36]:
6.4. Stage 4 (S4)—Turn-off Transition
- 4.
- In the t7–t8 time interval, the observations are very similar to those in the t3–t4 time interval. The HEMT device moves into a linear region from an ohmic conducting state. Vdrain increases to a boundary voltage of . Assuming that the peak current is unchanged, and , the t7–t8 time interval, Von_f, and the power losses in this time interval (Pturn_on_mf) can be written as follows:
- 5.
- In the t8–t9 time interval, the observations are very similar to those in the t2–t3 time intervals. Vdrain continues to increase more quickly towards the off-state Vds_off, while Idrain decreases slightly to ir. This current drop is caused by a charging shunt to other peripheral devices [33], and the current path through the device is illustrated in Figure 5d. Assuming that the Miller voltage (Vmf) remains unchanged and the current-dependent charging time of Coss can no longer be ignored, we have the following equation:
- 6.
- In the t9–t10 time interval, the observations are similar to those in the t1–t2 time interval. Idrain decreases from ir to a low value because the current begins to divert from the HEMT device to D1. In this time interval, the drain voltage is in a state of resonance, while Vgs decreases to (Vmr − Vth), and the device channel current reaches zero at t10 [20]. Then, the t9–t10 time interval and the power losses at this time interval (Pturn_off_cf) can be written as follows:
- 7.
- During the t10–t11 time interval, the device is turned off, but Vdrain ringing occurs due to the resonance between Coss and Lstray. These fluctuations of the drain voltage will lead to a slight power loss, which depends on the ringing peak voltage (Vds_pk). Assuming that the reverse recovery of D1 is zero, we have the following equation:
7. Model Verification via Experiments
8. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Glossary
Gate voltage. | |
Gate voltage in high level. | |
Gate voltage in low level. | |
Miller gate voltages during the turn-on transition. | |
Miller gate voltages during the turn-off transition. | |
Threshold voltage. | |
Total turn-on time during the turn-on transition. | |
Turn-on delay time. | |
Turn-on current rise time. | |
Turn-on voltage fall time. | |
Turn-on Miller rise time. | |
Turn-on gate voltage rise remaining time. | |
Total turn-off time during the turn-off transition. | |
Turn-off delay time. | |
Miller fall time. | |
Voltage rise time. | |
Current fall time. | |
Voltage continuous rise time. | |
Gate-source charge. | |
Gate-drain charge. | |
Overcharge gate charge. | |
Total gate charge, equal to the sum of Qgs, Qgd, and Qod. | |
Drain-source current. | |
Start drain-source current at turn-on transition. | |
Peak drain-source current during on-state. | |
Drain-source voltage. |
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Lei, J.; Liu, Y.; Yang, Z.; Chen, Y.; Chen, D.; Xu, L.; Yu, J. An Analytical Model of Dynamic Power Losses in eGaN HEMT Power Devices. Micromachines 2023, 14, 1633. https://doi.org/10.3390/mi14081633
Lei J, Liu Y, Yang Z, Chen Y, Chen D, Xu L, Yu J. An Analytical Model of Dynamic Power Losses in eGaN HEMT Power Devices. Micromachines. 2023; 14(8):1633. https://doi.org/10.3390/mi14081633
Chicago/Turabian StyleLei, Jianming, Yangyi Liu, Zhanmin Yang, Yalin Chen, Dunjun Chen, Liang Xu, and Jing Yu. 2023. "An Analytical Model of Dynamic Power Losses in eGaN HEMT Power Devices" Micromachines 14, no. 8: 1633. https://doi.org/10.3390/mi14081633
APA StyleLei, J., Liu, Y., Yang, Z., Chen, Y., Chen, D., Xu, L., & Yu, J. (2023). An Analytical Model of Dynamic Power Losses in eGaN HEMT Power Devices. Micromachines, 14(8), 1633. https://doi.org/10.3390/mi14081633