Insulated gate bipolar transistor physical model

Information

  • Patent Grant
  • 11875869
  • Patent Number
    11,875,869
  • Date Filed
    Wednesday, November 17, 2021
    3 years ago
  • Date Issued
    Tuesday, January 16, 2024
    11 months ago
  • Inventors
  • Original Assignees
    • NAVAL UNIVERSITY OF ENGINEERING
  • Examiners
    • Doan; Nghia M
    Agents
    • MATTHIAS SCHOLL P.C.
    • Scholl; Matthias
Abstract
An IGBT physical model parameter extraction method includes obtaining an initial value and a transformation range of an IGBT physical model parameter; and correcting a model parameter by means of a correspondence between IGBT dynamic and static features and the IGBT physical model parameter and in combination with an experiment measurement result of the IGBT physical model parameter.
Description
BACKGROUND

The disclosure relates to the field of modeling and reliability of power electronic devices, and more particularly to an IGBT physical model parameter extraction method.


For an IGBT (Insulated Gate Bipolar Transistor) with a certain structure, the internal parameters of the components have a decisive influence on its performance. These parameters include structure size, doping concentration, lifetime of excess carrier, junction capacitance, transconductance, etc., and they will directly affect various dynamic and static performance indicators of the IGBT, such as on-state voltage drop, switching speed, turn-off tail current. Therefore, to establish an accurate IGBT semiconductor physical model and realize an accurate simulation of the electrical characteristics of the IGBT, an accurate extraction of parameters is indispensable. At the same time, the model parameters are also important for the design and manufacturing of the IGBT, the structure and performance optimization, and the safe use of the components.


A semiconductor physical model is a simulation model that characterizes the electrical characteristics of IGBT components. Since the semiconductor physical model can achieve a compromise between the simulation accuracy and the simulation efficiency, it has become a widely used IGBT model. In order to continuously improve the overall performance of the products and obtain the optimization of various performance indicators, the component manufacturers usually optimize each parameter during the manufacturing process of the IGBT, such as changing the lifetime of excess carrier of the IGBT by neutron irradiation, and improving the switching performance through buffering layer technology. IGBTs produced by different manufacturers are similar in structure, and their performance often depends on specific internal process parameters.


At present, there are two methods for extracting the IGBT physical model parameters. One is estimating the parameters by combing the directly measured electrical parameters of three ports of the IGBT with some empirical formulas. The other is indirectly extracting the internal physical parameters of the IGBT through designed circuits. The former has a large error, so that it is difficult to meet the accuracy requirements. The latter has tedious extraction steps and it is affected by the accuracy of extraction circuit, so that the extraction of the parameters is difficult to meet the requirements of the simulation accuracy, and the operability is poor.


SUMMARY

The purpose of the disclosure is to provide an IGBT physical model parameter extraction method aiming at defects in the prior art, so that the IGBT physical model parameter extraction method can be greatly simplified while the requirement of parameter extraction on model simulation precision is ensured, and the practicability of an IGBT physical model is improved.


The disclosure provides an IGBT physical model parameter extraction method, the method comprising: obtaining an initial value and a transformation range of an IGBT physical model parameter; and correcting a model parameter according to the correspondence between IGBT dynamic and static features and the IGBT physical model parameter and in combination with an experiment measurement result of the IGBT physical model parameter.


In a class of this embodiment, the dynamic and static features of the IGBT module under a typical working condition are obtained from a data handbook. A typical value of the relevant parameter of the IGBT physical model is obtained by the theoretical calculations. A reasonable variation range of the typical value of the IGBT physical model parameters is obtained based on the semiconductor physical mechanism.


In a class of this embodiment, the correspondence between the IGBT physical model parameter and the IGBT dynamic and static features is determined by analyzing the influence law and degree of the IGBT physical model parameter and the temperature on the IGBT dynamic and static features.


In a class of this embodiment, in combination with the experiment measurement result of the IGBT physical model parameter, the IGBT physical model parameter is first corrected according to the dynamic and static features that are only affected by a single parameter, and then the IGBT physical model parameter is sequentially corrected starting from a dominant parameters according to the dynamic and static features affected by a coupling of multiple IGBT physical model parameters, and finally a temperature coefficient of the IGBT physical model parameter is corrected according to the variation of the dynamic and static features under different temperatures. At last, a correction result of the IGBT physical model parameter under different temperatures is obtained and the extraction of the model parameter is finished.


In a class of this embodiment, on the basis of the initial value and reasonable range of the IGBT physical model parameters, the model parameter is corrected at a temperature of 25° C. according to the influence trend and degree of the IGBT physical model parameter on IGBT switching transient characteristics. According to an approximate linear relationship between the IGBT transient characteristics and the temperature, a temperature empirical formula inside the model are corrected at a temperature of 125° C., so that the IGBT physical model parameter can accurately represents the IGBT switching transient characteristics within an entire temperature range.


In a class of this embodiment, the method for calculating the initial values and reasonable ranges of the IGBT physical model parameter is as follows:


(1) Base Doping Concentration NL:











N
L

=

1.932
×

10
18



V
B

-
1.4




;




symmetrical


structure



(
1-a)














V
B

=




W
L

[


2



qN
L

(

8
×

10
3




N
L

-
0.75



)




ε
Si



ε
0



]


1
2


-




qN
L



W
L
2



2


ε
Si



ε
0



.






asymmetrical


structure



(
1-b
)








In the above formulas, VB represents a forward breakdown voltage of a collector-emitter of IGBT, WL represents a base width, q represents an electron charge constant, εsi represents a relative permittivity of silicon, and ε0 represents a permittivity of air.


(2) Base Width WL:










W
L

=

2.67
×


10
10

·


N
L



7
8



.







(
2
)







(3) Lifetime of Excess Carrier in Base Region τL:










τ
L

=



t
off


ln
[

1

0


α

p

n

p



]


.





(
3
)













α

p

n

p


=

sec



h

(


W
L


L
L


)

.






(
4
)







In the above formulas, αpnp represents a common base current amplification factor of parasitic PNP transistor in the IGBT, toff represents a current turn-off time of IGBT, LL represents a hole diffusion coefficient of the base region.


(4) Trans-Conductance Coefficient Kp:











K
p

=


2
×

I

M

O

S


s

a

t





(


V

G

S


-

V

t

h



)

2



;




(
5
)















I


M

O

S


s

a

t


=


I

C

E


s

a

t



1
+

β

s

s





;




(
6
)













β

s

s


=





1
b



P
0


+


Q
1

(


1
b

+

1

cos


h

(


W

(
t
)


L
L


)




)




P
0

+


Q
1

(

1
-

1

cos


h

(


W

(
t
)


L
L


)




)



.





(
7
)







In the above formulas, P0 represents a concentration of the excess carrier of the base region near an edge of a collector PN junction, Q1 represents an equivalent carrier charge of the base region, IMOSsat represents a saturation current of MOSFET, VGS represents a gate-emitter voltage of IGBT, Vth represents a threshold voltage of IGBT, ICEsat represents an on-state current of IGBT, βss represents an equivalent current amplification coefficient of IGBT, W(t) represents a quasi-neutral base width, b represents a ratio of electron mobility to hole mobility, and LL represents a hole diffusion coefficient of the base region; Kp can be obtained by putting VGS, Vth and ICEsat into the formulas, ICEsat and the corresponding VGS can be obtained from a device data handbook.


(5) Gate Oxide Layer Capacitance COXD:


According to a junction capacitance expression, an initial value of a gate-collector capacitance CGDJ can be estimated firstly, and then an initial value of the gate oxide layer capacitance COXD can be obtained through a Miller capacitance CGD, and the Miller capacitance CGD can be obtained from the data handbook.


(6) Gate-Emitter Capacitance CGS:


The gate-emitter capacitance CGS can be approximately equal to the difference between an input capacitance Cies of IGBT and a feedback capacitance Cres of IGBT. Therefore, an initial value and the reasonable order of magnitude of the gate-emitter capacitance CGS can be calculated by the following formula (8), wherein the feedback capacitance Cres and the input capacitance Cies can be directly obtained from the data handbook.

CGS=Cies−Cres  (8).


(7) Other Model Parameters:


An initial value and reasonable correction range of the threshold voltage Vth can be obtained from the data handbook. A structure size parameter can be obtained by physical measurement. According to the information disclosed by an IGBT manufacturer, a reference concentration of a buffer layer NH, the lifetime of the excess carrier of the buffer layer τH and a reasonable orders of magnitude of a buffer layer width WH can be obtained. A lifetime of minority carrier in the buffer layer of IGBT is determined by a doping concentration of the carrier. When a dispersion range of a semiconductor process parameter is put into a calculation formula of an initial value of the parameter, the variation range of the initial value of the model parameter can be obtained, so that the initial value of the model parameter and its reasonable ranges can be determined.


In a class of this embodiment, the model parameters that affect a turn-on delay tdon are the gate-emitter capacitance CGS, the threshold voltage Vth and the Miller capacitance CGS. The model parameters that affect a current rise time tr are the trans-conductance coefficient Kp, the threshold voltage Vth, the gate-emitter capacitance CGS and the base doping concentration NL. The model parameters that affect a turn-off delay taw are the gate-emitter capacitance CGS, the threshold voltage Vth, the trans-conductance coefficient Kp and the gate oxide layer capacitance Coxa. The model parameters that affect a current fall time tf are the lifetime of excess carrier in the buffer layer τH, the lifetime of excess carrier in the base region τL, the width of the buffer layer WH, the base width WL and the base doping concentration NL.


In a class of this embodiment, the IGBT physical model parameter related to the temperature can be calculated by the following temperature empirical formulas.











τ

(

T
j

)

=


τ

(

T
0

)

×


(


T
j


T
0


)

a



;




(
12
)
















V

t

h


(

T
j

)

=



V

t

h


(

T
0

)

-

b
×

(


T
j

-

T
0


)




;






(
13
)
















K
p

(

T
j

)

=



K
p

(

T
0

)

×


(


T
j


T
0


)

c



;




(
14
)
















I

sne

(

T
j

)

=





I
sne

(

T
0

)

×


(


T
j


T
0


)

d



exp
[


(


1
/

T
j


-

1
/

T
0



)

×
e
×

10
4


]


.





(
15
)








In the above formulas, a, b, c, d, e are the temperature coefficients related to actual operation characteristics, and they are determined according to an actual device. τ(T0), Vth(T0), Kp(T0) and Isne(T0) represent the lifetime of excess carrier r, the threshold voltage Vth, the trans-conductance coefficient and an electron saturation current of the emitter at a temperature of T0, respectively. τ(Tj), Vth(Tj), Kp(Tj) and Isne(Tj) represent the values of the aforementioned physical parameters at a temperature of Tj, respectively. Generally, To is equal to 25° C. Tj represents an actual operating junction temperature.


In a class of this embodiment, the IGBT dynamic and static features that are least affected by a coupling of the model parameter are preferentially chosen, and then the IGBT physical model parameter that have a greater impact on the IGBT dynamic and static features is preferentially corrected, so that the IGBT switching transient characteristics represented by the model having the corrected parameter are closer to the value recorded in the data handbook at a temperature of 25° C. The IGBT dynamic and static features that are least affected by a coupling of the temperature-related model parameter are preferentially chosen to correct the temperature coefficient.


In a class of this embodiment, the corrected model parameter is excluded. For the rest IGBT dynamic and static features to be adjusted, the characteristics that have the least coupling relationship with the parameter are chosen to perform the next parameter correction. When the IGBT dynamic and static features meet the requirements within a reasonable range for the first time, the correction of the IGBT physical model parameter is terminated immediately.


In this invention, the initial value of the IGBT physical model parameter and its reasonable correction range is firstly obtained based on the information provided by the data handbook and the typical calculations. Then, the parameter is corrected based on the influence law and degree of each parameter on the IGBT switching transient characteristics. Finally, simulation and experimental verification are conducted on the IGBT physical model based on the corrected parameter. The result shows that the physical model parameter obtained by this method can accurately represent the IGBT switching transient characteristics. Because only the device data handbook and the model calculation are used in this method and a complicated circuit extraction method is not required, this invention significantly reduces the difficulties of the extraction of the IGBT physical model parameter and improves the practicability of the IGBT physical model.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a structure diagram of an IGBT with a buffer layer;



FIG. 2 is a waveform diagram of the IGBT during a switching process;



FIG. 3 shows a variation rule of tdon with Vth under different temperatures;



FIG. 4 shows a variation rule of tr with Kp under different temperatures;



FIG. 5 shows a variation rule of tr with Vth under different temperatures;



FIG. 6 shows a variation rule of tdoff with Vth under different temperatures;



FIG. 7 shows a variation rule of tf with τL under different temperatures;



FIG. 8 shows a variation rule of tf with τH under different temperatures;



FIG. 9 shows a variation rule of tr with Tj;



FIG. 10 shows a variation rule of tf with Tj;



FIG. 11 shows a variation rule of Eon with Tj;



FIG. 12 shows a variation rule of Eoff with Tj;



FIG. 13 shows an IGBT double pulse simulation test circuit; and



FIG. 14 is a flow diagram of an IGBT physical model parameter extraction method.





DETAILED DESCRIPTION

Specific embodiments of the invention are further described in details combining with the drawings hereinbelow.


This invention provides an IGBT physical model parameter extraction method, characterized by comprising the following steps of: obtaining an initial value and a transformation range of an IGBT physical model parameter; and correcting a model parameter according to the correspondence between IGBT dynamic and static features and the IGBT physical model parameter and in combination with an experiment measurement result of the IGBT physical model parameter. The method specially comprises the following steps.


1. Determination of the Initial Value and Reasonable Range of the IGBT Physical Model Parameter



FIG. 1 shows a typical structure diagram of the IGBT. The physical model parameter mainly includes the parameter directly related to the semiconductor process, such as Vth, CGS, COXD, Kp, NL, WL, WH, τL, τH. In the process of model parameter correction, if the value of the parameter exceeds the reasonable range, the model will lose its physical meaning. Therefore, the initial value of the parameter and its reasonable correction range should be determined firstly before the parameter correction. The specific calculation method is as follows.


(1) Base Doping Concentration NL


According to the semiconductor theory, a depletion layer mainly extends in N-base region during forward blocking, and the base doping concentration plays a key role in the forward blocking performance of the IGBT. Therefore, the initial value of NL and its reasonable order of magnitude can be estimated according to the formula (1), wherein VB represents the breakdown voltage:













N
L

=


1
.
9


3

2
×
1


0

1

8




V
B

-
1.4




;





Symmetrical


structure


(

1
-
a

)















V

B

=




W
L

[


2

q



N
L

(

8
×
1


0
3



N
L

-
0.75



)




ε
Si



ε
0



]


1
2


-



q


N
L



W
L
2



2


ε
Si



ε
0



.






Asymmetrical


structure



(

1
-
b

)








(2) Base Width WL


Since the breakdown voltage is closely related to the base doping concentration and the base width, and the size of the base width depends on the base doping concentration, the initial value of WL can be calculated by the formula (2) and the formula (1):










W
L

=


2
.
6


7
×
1



0

1

0


·


N
L

-

7
8



.







(
2
)







(3) Lifetime of Excess Carrier in Base Region τL


The order of magnitude of the lifetime of the excess carrier in the base region can be estimated by toff and semiconductor theory formulas. toff can be obtained from the device handbook.









[



τ
L

=


t
off


ln
[

10


α
pnp


]



;





(
3
)













α

p

n

p


=

sec



h
(


W
L


L

L

p



)

.






(
4
)







In the above formulas, αpnp represents the common base current amplification factor of parasitic PNP transistor in the IGBT, toff represents the current turn-off time of IGBT, LLp represents the hole diffusion coefficient of the base region.


(4) Trans-Conductance Coefficient Kp


The initial value of Kp can be calculated by combining the following equations:











K
p

=


2
×

I

M

O

S


s

a

t





(


V

G

S


-

V

t

h



)

2



;




(
5
)















I


M

O

S


s

a

t


=


I

C

E


s

a

t



1
+

β

s

s





;




(
6
)













β

s

s


=





1
b



P
0


+


Q
1

(


1
b

+

1

cos


h

(


W

(
t
)


L
L


)




)




P
0

+


Q
1

(

1
-

1

cos


h

(


W

(
t
)


L
L


)




)



.





(
7
)







In the above formulas, P0 represents the concentration of the excess carrier of the base region near the edge of the collector PN junction, Q1 represents the equivalent carrier charge of the base region, IMOSsat represents the saturation current of MOSFET. Kp can be obtained by putting VGS, Vth and ICEsat into the formulas. ICEsat and the corresponding VGS can be obtained from the device data handbook.


(5) COXD


According to the junction capacitance expression, the initial value of the gate-collector capacitance CGDJ can be estimated firstly, and then the initial value of the gate oxide layer capacitance COXD can be obtained through the Miller capacitance CGD. The Miller capacitance CGD can be obtained from the data handbook.


(6) CGS


The gate-emitter capacitance CGS can be approximately equal to the difference between an input capacitance Cies of IGBT and the feedback capacitance Cres of IGBT. Therefore, the initial value and the reasonable order of magnitude of the gate-emitter capacitance CGS can be calculated by the formula (8), wherein Cres and Cies can be directly obtained from the data handbook.

CGS=Cies−Cres  (8)


(7) Other Model Parameters


The initial value and reasonable correction range of the threshold voltage Vth can be obtained from the data handbook. The structure size parameter can be obtained by physical measurement.


According to the information disclosed by the IGBT manufacturer, the reasonable order of magnitude of NH, τH and WH can be obtained. According to the semiconductor theory, the lifetime of minority carrier in the buffer layer of the IGBT is determined by the doping concentration of the carriers. When the dispersion range of the semiconductor process parameter are put into the calculation formulas of the initial value of the parameter, the variation range of the initial value of the model parameter can be obtained, so that initial value of the model parameter and its reasonable range can be determined.


2. Analysis of the Influence Law and Degree of the IGBT Physical Model Parameter on the Characteristics of the IGBT


2.1 Analysis of the Influence Law and Degree of the Model Parameter on the Turn-on Characteristics of the IGBT Under a Constant Temperature


As shown in FIG. 2, the turn-on time of the IGBT can be divided into two parts, namely a turn-on delay time tdon and a turn-on rise time tr. On basis of the established physical model, a simulation is conducted on the influence of each parameter on tdon and tr within the reasonable ranges of typical parameter values, wherein the model parameters are used as variables. In the phase of turn-on delay, a drive circuit charges the CGS, and VGE(t) gradually increases from lower than Vth to higher than Vth. When VGE(t)=Vth, the IGBT is turned on and ICE gradually increases from zero. Therefore, τdon is related to CGS, Vth and CGS.


The variation of the rising rate of ICE will directly affect tr. ICE includes MOSFET channel current Imos, IGBT collector-emitter hole current IP and charge-discharge current of internal junction capacitance Ic.

ICE=Imos+IP+Ic  (9)


In accordance with the principle of MOSFET, the variations of Kp, Vth and CGS will have an impact on Imos. As known from the expression (10) of the hole current of the physical model, the model parameters related to IP are NL, τL, WH and WL.










I
P

=




(

1
+


B
b

·


3


W
H
2



2


D

p

H




τ
L





)




I
CE


1
+
b



+


B
b




Q
T

(



6


D
L




W
2

(
t
)


+



C

B

C

J





dV
AA

dt



q

A


W

(
t
)



N
L



-

1

τ
L



)




1
+


B
b

(



3


D
L





W
2

(
t
)



D

p

H




+



W
H
2



C
BCJ




dV
AA

dt



2

q

A


W

(
t
)



D

p

H




N
L



+


W
H
2



D

p

H




τ
L




)







(
10
)







In the above formula, Bb, QT, WH, DpH and CBCJ are the semiconductor parameters related to the physical model.


Therefore, the model parameters that affect tr are Kp, Vth, CGS and NL.


2.2 Analysis of the Influence Law and Degree of the Model Parameter on the Turn-Off Characteristics of the IGBT Under a Constant Temperature


As shown in FIG. 2, the turn-off time of the IGBT can be divided into two parts, namely a turn-off delay time taw and a turn-off fall time tf. It can be known from the analysis of the waveform of the turn-off delay phase that VGE(t) gradually decreases from VGG to VGP with the discharge of CGS. VGP is only related to Vth and Kp.










V

G

P


=




t

h



+



(


I
P

+

I
n


)


K
p









(
11
)







In the phase of [t6-t7], VGE(t) is in a Miller plateau. Therefore, CGS, Vth, Kp and COXD will have an impact on tdoff.


The turn-off fall phase of the IGBT can be divided into two parts. a) When VGE(t) drops slightly less than Vth, the conductive channel in the MOSFET disappears and the channel current rapidly drops to zero. b) Although the electron current disappears rapidly, a large number of excess carriers are still left inside the IGBT. The excess carriers will gradually disappear through recombination, which will result in a “tailing” of the turn-off current. As the phase a) is finished in an instant, the effect of this period on tf is negligible. The slower recombination process of the excess carrier becomes the main factor that affects tf. According to the semiconductor theory, the greater the carrier recombination rate, the stronger the recombination effect and the smaller tf. The recombination rate is related to the lifetime and the concentration of the excess carriers. Therefore, the model parameters related to tf are τH, τL, WH, WL, NL.


The simulation result of the influence law and degree of the model parameter on the IGBT transient characteristics are shown in FIGS. 3-8 and Table 1.









TABLE 1







The influence law and degree of the IGBT physical model


parameter on the characteristics under switching transient


(The direction of the arrow indicates the law of influence, and


the number of arrows indicates the degree of the influence)














tdon/μs
tr/μs
tdoff/μs
tf/μs
Eon/mJ
Eoff/mJ





Vth/V↑
↑↑
↑↑↑↑
↓↓↓

↑↑↑↑



CGS/F↑








COXD/F↑


↑↑↑↑





Kp/A/V2

↓↓↓
↑↑

↓↓↓



NL/cm−3

↑↑

↓↓↓↓
↑↑
↓↓


WL/cm↑



↓↓↓↓↓

↓↓↓↓↓


WH/cm↑



↓↓↓

↓↓↓↓


τL/s↑








τH/s↑



↑↑

↑↑↑









2.3 Analysis of the Influence Law and Degree of the Temperature on the Characteristics of the IGBT


The parameters of the components related to the temperature can be calculated by the following temperature empirical formulas.











τ

(

T
j

)

=


τ

(

T
0

)

×


(


T
j


T
0


)

a



;




(
12
)















V

t

h


(

T
j

)

=



V

t

h


(

T
0

)

-

b
×

(


T
j

-

T
0


)




;




(
13
)















K
p

(

T
j

)

=



K
p

(

T
0

)

×


(


T
j


T
0


)

c



;




(
14
)















I

sne

(

T
j

)

=





I
sne

(

T
0

)

×


(


T
j


T
0


)

d



exp
[


(


1
/

T
j


-

1
/

T
0



)

×
e
×

10
4


]


.





(
15
)







In the above formula, the temperature coefficients a, b, c, d, e are positive, and they are related to the actual operation characteristics. τ(T0), Vth(T0), Kp(T0) and Isne(T0) represent the lifetime of the excess carrier, the threshold voltage, the trans-conductance coefficient and the electron saturation current of the emitter at a temperature of T0, respectively. τ(Tj), Vth(Tj), Kp(Tj) and Isne(Tj) represent the values of the aforementioned physical parameters at a temperature of Tj, respectively. Generally, T0 is equal to 25° C. Tj represents an operating junction temperature. The influence of the operating junction temperature of the IGBT on the switching transient characteristics of the IGBT can be obtained by combing the relationship between these parameters related to temperature and the variation of the temperature as well as the relationship between the parameters and the IGBT switching transient characteristics. The simulation result is shown in FIGS. 9-12.


3. The Correction Method of the IGBT Physical Model Parameter


Based on the initial value and the reasonable range of the parameter, the model parameter is corrected at a temperature of 25° C. according to the influence trend and degree of the parameter on the IGBT transient characteristics. According to an approximate linear relationship between the IGBT transient characteristics and the temperature, the temperature empirical formula inside the model will be corrected at a temperature of 125° C., so that the IGBT physical model parameters can accurately represent the IGBT switching transient characteristics within an entire temperature range.


(1) Correction of the Model Parameter at a Temperature of 25° C.


Considering the wide variety of the model parameters and their complex coupling effects on the IGBT switching transient characteristics, according to the influence trend and degree of the model parameter on the IGBT transient characteristics, the IGBT characteristics that are least affected by the coupling of the model parameter is preferentially chosen, and then the preferentially corrected parameter is chosen according to the influence degree of the parameter on the characteristics, so that the IGBT switching transient characteristics represented by the model having the corrected parameters are closer to the values recorded in the data handbook at a temperature of 25° C. The correction process is as follows:


i) tdon


As shown in Table 1, in the IGBT switching transient characteristics, the least parameters related to tdon is Vth and CGS, and CGS has a greater impact on tdon. Therefore, CGS is preferred chosen and CGS will be corrected according to the influence rule of CGS on tdon that shown in the Table 1. When tdon meets the requirements for the first time, the correction to CGS is immediately terminated. Otherwise, Vth can be further corrected. The method of the correction is the same as that of CGS.


ii) tr


The corrected model parameters are excluded. For the rest IGBT dynamic and static characteristics to be adjusted, the characteristics that have the least coupling relationship with the parameters are chosen to perform the next parameter correction. As shown in the Table 1, only Kp and NL are left. Considering the requirements on the forward blocking of the IGBT, a large adjustment to NL should be avoided during the correction, so that Kp is preferred for correction. According to the variation rule of tr with Kp, when tr meets the requirements for the first time, the correction of Kp can be terminated. Otherwise, a fine-tuning is performed on NL to make tr meet the requirements, and then the correction of NL can be terminated.


iii) Eon


So far, the debugging of the transient characteristics related to the turn-on time of the IGBT has been finished. If the turn-on time of the IGBT meets the requirements, Eon will also meet the requirements at the same time.


iv) tdoff


Except for the above corrected parameters, among the remaining characteristics to be adjusted, the only parameter that affects tdoff is COXD. Thus, the COXD is corrected based on the rules shown in the table to make tdoff meet the requirements for the first time. Then, the correction can be terminated.


v) tf and Eoff


The other modifiable parameters have a coupling effect on Eoff and tf at the same time. However, since Eoff is not only related to tf but also closely related to the turn-off tail current, tf is preferred for debugging. WH and τH have a greater impact on the tail current, so that WL and τL are preferred for correction when debugging tf.


According to the variation rule of tf with WL, WL is corrected. When tf meets the requirements for the first time, the correction to WL can be terminated. Otherwise, τL is corrected until tf meets the requirements. At the same time, if Eoff also meets the requirements, the parameter correction is finished. Otherwise, τH is corrected. When hand Eoff meet the requirements at the same time, the correction is terminated and the correction of the model parameters at a temperature of 25° C. is finished.


(2) Correction of the Model Parameters at a Temperature of 125° C.


Similar to the correction process under a temperature of 25° C., the IGBT characteristics that are least affected by the coupling of the model parameters related to the temperature are preferentially chosen, and the temperature coefficients are corrected. The analysis of the correction process is as follows.


i) tdon


It is preferred to choose the temperature coefficient a that corrects Vth. When tdon meets the requirements for the first time, the correction to the temperature coefficient a will be terminated.


ii) tr


The temperature coefficient b of the characteristic tr-Kp that is least affected by the coupling of the temperature-related parameters is chosen to be corrected. When tr meets the requirements for the first time, the correction to b can be terminated.


iii) tdoff


Since the hole saturation drift velocity νsat,p decreases with the increase of the temperature, taw increases with the increase of the temperature. Therefore, tdoff can be adjusted by correcting the temperature coefficient of νsat,p.


iv) tf and Eoff


According to the requirements of tf and Eoff, the temperature coefficients of τL and τH are corrected at the same time so as to complete the correction of the temperature coefficient at a temperature of 125° C.


4. Extraction Method of the IGBT Physical Model Parameter


Based on the above analysis method and conclusion, the IGBT physical model parameters extraction method is as follows. The dynamic and static characteristics of the IGBT module under a typical working condition are obtained from the data handbook. The typical values of the physical model parameters are obtained through theoretical calculations. Then, the reasonable variation ranges of the typical values of the model parameters are obtained based on the semiconductor physical mechanism. Next, the correspondence between the model parameters and the IGBT dynamic and static characteristics is determined by analyzing the influence law and degree of the model parameters and the temperature on the IGBT dynamic and static characteristics. Further, based on the actual test result, the parameter is corrected in term of the characteristic that only affected by a single parameter firstly. Then, in term of the characteristics affected by the multi-parameter coupling, the dominant parameters are corrected in turn. At last, the temperature coefficient of the parameter is corrected by combining the characteristic variations under different temperatures. Finally, the correction results of the model parameters under different temperatures are obtained, and the extraction of the model parameters is realized. The flow chart of the extraction method is shown in FIG. 14.


5. Experimental Verification


The simulation and the experimental verification are performed on Infineon 3300V/1500 A IGBT module. Firstly, based on the established physical model, an IGBT double pulse test simulation is performed on the improved model according to the initial value and the corrected value of the model parameters. The simulation and the test circuit are shown in FIG. 13, wherein L=90 uH, Rgon=0.9Ω, Rgoff=2.7Ω, ICE=1500 A, VDC=1800V, LS=40 nH, CGE=330 nF.


Table 2 shows the values of the model parameters extracted by the method of this invention. Table 3 shows the comparison between the double-pulse simulation result of the IGBT module using the initial values of the model parameters and the double-pulse simulation result of the IGBT module using the extraction values of the present invention. It can be seen that the simulation result of this invention are in good agreement with the actual measurement result, which verifies the correctness of the IGBT physical model parameter extraction method of this invention.









TABLE 2







The initial values and extraction values of the


parameters of Infineon FZ1500R33HL3 IGBT model












Initial
Extraction value of



Parameter
value
this invention















WL/cm
0.044
0.048



τL/S
5 × 10−6
6.5 × 10−6



Vth/V
5.8
6



CGS/F
1.2 × 10−9
2.5 × 10−9



COXD/F
  5 × 10−8
7.8 × 10−8



τH/S
 5 × 10−7
 3 × 10−7



Kp/A/V2
3.0
5.0



a(τL)
1.5
1.0



a(τH)
1.5
1.0



C
−1.5
−1.0

















TABLE 3







Comparison of the parameter extraction effect of Infineon


FZ1500R33HL3 IGBT module physical model









Junction Temperature










25° C.
125° C.















Simulation


Simulation





result


result




Simulation
based on

Simulation
based on




result based
the extraction

result based
the extraction



Comparison
on the
value of this
Test
on the
value of this
Test


item
initial value
invention
value
initial value
invention
value
















tdon/μs
0.21
0.52
0.5
0.55
0.52
0.5


tr/μs
0.2
0.54
0.55
0.8
0.57
0.55


tdoff/μs
2.35
3.7
4.1
3.128
4.345
4.3


tf/μs
0.21
0.36
0.4
0.48
0.36
0.4


Eon/mJ
1222.8
2389.3
2300
1617.1
3264.7
3200


Eoff/mJ
1146.6
2579.3
2400
1923.1
3100
2950









It will be obvious to those skilled in the art that changes and modifications may be made, and therefore, the aim in the appended claims is to cover all such changes and modifications.

Claims
  • 1. An insulated gate bipolar transistor (IGBT) physical model parameter extraction method, comprising: obtaining an initial value and a transformation range of an IGBT physical model parameter; and correcting a model parameter according to a correspondence between IGBT dynamic and static features and the IGBT physical model parameter and in combination with an experiment measurement result of the IGBT physical model parameter; wherein: the IGBT dynamic and static features under a typical working condition are obtained from a data handbook; a typical value of the relevant parameter of an IGBT physical model is obtained by a theoretical calculation; and a reasonable variation range of the typical value of the IGBT physical model parameter is obtained according to a semiconductor physical mechanism;the calculation of the initial value and reasonable range of the IGBT physical model parameter comprises:(1) base doping concentration NL:
  • 2. The method of claim 1, wherein the correspondence between the IGBT physical model parameter and the IGBT dynamic and static features is determined by analyzing an influence law and degree of the IGBT physical model parameter and a temperature on the IGBT dynamic and static features.
  • 3. The method of claim 2, wherein the IGBT physical model parameter related to temperature is calculated by the following temperature empirical formulas:
  • 4. The method of claim 1, wherein in combination with the experiment measurement result of the IGBT physical model parameter, the IGBT physical model parameter is first corrected according to the dynamic and static features that are only affected by a single parameter, and then the IGBT physical model parameter is sequentially corrected starting from a dominant parameter according to the dynamic and static features affected by a coupling of multiple IGBT physical model parameters, and a temperature coefficient of the IGBT physical model parameter is corrected according to the variation of the dynamic and static features under different temperatures, and at last, a correction result of the IGBT physical model parameter under different temperatures is obtained and the extraction of the model parameter is finished.
  • 5. The method of claim 4, wherein on the basis of the initial value and reasonable range of the IGBT physical model parameter, the model parameter is corrected at a temperature of 25° C. according to the influence trend and degree of the IGBT physical model parameter on IGBT switching transient characteristics; according to an approximate linear relationship between the IGBT transient characteristics and the temperature, a temperature empirical formula inside the model is corrected at a temperature of 125° C., so that the IGBT physical model parameter accurately represents the IGBT switching transient characteristics within an entire temperature range.
  • 6. The method of claim 5, wherein the IGBT dynamic and static features that are least affected by a coupling of the model parameter are preferentially chosen, and then the IGBT physical model parameter that have a greater impact on the IGBT dynamic and static features is preferentially corrected, so that the IGBT switching transient characteristics represented by the model having the corrected parameter are closer to the value recorded in the data handbook at a temperature of 25° C.; the IGBT dynamic and static features that are least affected by a coupling of the temperature-related model parameter are preferentially chosen to correct the temperature coefficient.
  • 7. The method of claim 6, wherein the corrected model parameter is excluded, and for the rest IGBT dynamic and static features to be adjusted, the characteristics that have the least coupling relationship with the parameter are chosen to perform the next parameter correction; when the IGBT dynamic and static features meet the requirements within a reasonable range for the first time, the correction of the IGBT physical model parameter is terminated immediately.
  • 8. The method of claim 1, wherein the model parameters that affect a turn-on delay tdon are the gate-emitter capacitance CGS, the threshold voltage Vth and the Miller capacitance CGD; the model parameters that affect a current rise time tr are the trans-conductance coefficient Kp, the threshold voltage Vth, the gate-emitter capacitance CGS and the base doping concentration NL; the model parameters that affect a turn-off delay tdoff are the gate-emitter capacitance CGS, the threshold voltage Vth, the trans-conductance coefficient Kp and the gate oxide layer capacitance COXD; the model parameters that affect a current fall time tf are the lifetime of excess carrier in the buffer layer τH, the lifetime of excess carrier in the base region τL, the width of the buffer layer WH, the base width WL and the base doping concentration NL.
Priority Claims (1)
Number Date Country Kind
201910700605.4 Jul 2019 CN national
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of International Patent Application No. PCT/CN2019/121527 with an international filing date of Nov. 28, 2019, designating the United States, now pending, and further claims foreign priority benefits to Chinese Patent Application No. 201910700605.4 filed Jul. 31, 2019. The contents of all of the aforementioned applications, including any intervening amendments thereto, are incorporated herein by reference. Inquiries from the public to applicants or assignees concerning this document or the related applications should be directed to: Matthias Scholl P.C., Attn.: Dr. Matthias Scholl Esq., 245 First Street, 18th Floor, Cambridge, MA 02142.

US Referenced Citations (1)
Number Name Date Kind
20200240850 He Jul 2020 A1
Foreign Referenced Citations (2)
Number Date Country
102623335 Aug 2012 CN
104899350 Sep 2015 CN
Non-Patent Literature Citations (3)
Entry
Mitter et al., Insulated Gate Bipolar Transistor (IGBT) Modeling Using IG-Spice, IEEE, 1993, pp. 24-33. (Year: 1993).
Rodriguez et al., Static and Dynamic finite element modeling of thermal fatigue effects in insulated gate bipolar transistor modules, Microelectronic Reliability, Nov. 12, 1999, pp. 445-463 (Year: 1999).
CN 102623335 (electronic translation) (Year: 2012).
Related Publications (1)
Number Date Country
20220076777 A1 Mar 2022 US
Continuation in Parts (1)
Number Date Country
Parent PCT/CN2019/121527 Nov 2019 US
Child 17529230 US