WO2017115553A1 - 半導体装置 - Google Patents
半導体装置 Download PDFInfo
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- WO2017115553A1 WO2017115553A1 PCT/JP2016/082198 JP2016082198W WO2017115553A1 WO 2017115553 A1 WO2017115553 A1 WO 2017115553A1 JP 2016082198 W JP2016082198 W JP 2016082198W WO 2017115553 A1 WO2017115553 A1 WO 2017115553A1
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- H01L29/66—Types of semiconductor device ; Multistep manufacturing processes therefor
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- H01L29/7813—Vertical DMOS transistors, i.e. VDMOS transistors with trench gate electrode, e.g. UMOS transistors
Definitions
- the present invention relates to a semiconductor device.
- semiconductor devices using an n-type semiconductor substrate instead of a p-type semiconductor substrate for example, a low-side switch IC having a vertical structure MOSFET [metal-oxide-semiconductor field effect transistor]) have been used in various applications. ing.
- Patent Document 1 and Patent Document 2 can be cited as examples of conventional techniques related to the above.
- FIG. 9 is a vertical cross-sectional view schematically showing a conventional structure of a semiconductor device (only the minimum components necessary for understanding the problem).
- the semiconductor device A in this figure has an n-type semiconductor substrate A1, a p-type well A2 formed in the n-type semiconductor substrate A1, and an n-type semiconductor region A3 formed in the p-type well A2.
- the n-type semiconductor substrate A1 is connected to the output terminal OUT
- the p-type well A2 is connected to the ground terminal GND
- the n-type semiconductor region A3 is connected to the control terminal IN.
- the semiconductor device A using the n-type semiconductor substrate A1 is applied to an application in which the output terminal OUT can be at a lower potential than the ground terminal GND (for example, an application in which an inductive load is externally connected to the output terminal OUT). I could't.
- the invention disclosed in this specification is a semiconductor device that does not hinder operation even when an n-type semiconductor substrate becomes a negative potential.
- the purpose is to provide.
- a semiconductor device disclosed in the present specification is formed by controlling an n-type semiconductor substrate connected to an output terminal, a first p-type well formed in the n-type semiconductor substrate, and the first p-type well.
- the first p-type well and the ground terminal are set to the same potential when the potential is also high, and the first p-type well and the output terminal are set to the same potential when the output terminal is lower than the ground terminal ( First configuration).
- the potential separation section includes a second p-type well formed on the n-type semiconductor substrate and connected to the ground terminal, and a second n-type formed on the second p-type well.
- the first p-type well and the second n-type semiconductor region may be connected to the ground terminal via a common resistor (second configuration).
- the semiconductor device disclosed in this specification is formed in an n-type semiconductor substrate connected to an output terminal, a first p-type well formed in the n-type semiconductor substrate, and the first p-type well.
- a first n-type semiconductor region connected to the control terminal, and a potential separation portion connected between the first p-type well and the ground terminal, wherein the potential separation portion is formed on the n-type semiconductor substrate.
- a second p-type well formed and connected to the ground terminal; and a second n-type semiconductor region formed in the second p-type well.
- the first p-type well and the second n-type semiconductor region include: It is configured to be connected to the ground terminal via a common resistor (third configuration).
- the semiconductor device having the second or third configuration may be configured to further include an external terminal for externally attaching the resistor (fourth configuration).
- the second n-type semiconductor region corresponds to a back gate of a dummy PMOSFET formed in the second p-type well (fifth configuration).
- the semiconductor device having any one of the first to fifth configurations is connected between the output terminal and the ground terminal and is turned on / off in accordance with a control voltage input from the control terminal.
- the control unit is connected between a PMOSFET connected between the control terminal and the gate of the output transistor, and between the gate of the output transistor and the ground terminal.
- the first p-type well may correspond to a back gate of the NMOSFET, and the first n-type semiconductor region may correspond to a back gate of the PMOSFET (seventh configuration).
- An electronic device disclosed in the present specification includes a semiconductor device having any one of the first to seventh configurations, a microcomputer for supplying a control voltage to a control terminal of the semiconductor device, And a load externally attached to the output terminal (eighth configuration).
- the load may be an inductive load (9th configuration).
- the semiconductor device may be configured as a low-side switch IC, a switching power supply IC, or a motor driver IC (tenth configuration).
- the vehicle disclosed in the present specification has a configuration (an eleventh configuration) that includes the electronic device having the tenth configuration and a battery that supplies power to the electronic device.
- a longitudinal sectional view schematically showing the basic structure of a semiconductor device Application diagram showing application example to low-side switch IC
- a longitudinal sectional view schematically showing a first structural example of a semiconductor device Waveform diagram showing behavior during negative output Circuit diagram showing a specific example of a control unit and a potential separation unit
- External view showing a configuration example of a vehicle Longitudinal sectional view schematically showing a conventional structure of a semiconductor device
- FIG. 1 is a longitudinal sectional view schematically showing the basic structure of a semiconductor device (only the minimum components necessary for understanding the invention).
- the semiconductor device 10 in this figure includes an n-type semiconductor substrate 11 connected to an output terminal OUT, a p-type well 12 formed in the n-type semiconductor substrate 11, and a p-type well 12 connected to a control terminal IN.
- N-type semiconductor region 13 and potential separation portion 14 connected between p-type well 12 and ground terminal GND.
- the potential separation unit 14 includes a p-type well 14a formed on the n-type semiconductor substrate 11 and connected to the ground terminal GND, and an n-type semiconductor region 14b formed in the p-type well 14a.
- the p-type well 12 and the n-type semiconductor region 14b are connected to the ground terminal GND through a common resistor 14c.
- the node voltage of the p-type well 12 is expressed as GND_ref.
- parasitic transistors Q1 and Q2 are attached to the semiconductor device 10 in the drawing.
- the parasitic transistor Q1 is an npn-type bipolar transistor having an n-type semiconductor substrate 11 as an emitter, a p-type well 12 as a base, and an n-type semiconductor region 13 as a collector.
- the parasitic transistor Q2 is an npn-type bipolar transistor having the n-type semiconductor substrate 11 as an emitter, the p-type well 14a as a base, and the n-type semiconductor region 14b as a collector.
- the parasitic transistor Q2 is not turned on because the base-emitter of the parasitic transistor Q2 is reverse-biased. Therefore, the current I2 does not flow in the path from the ground terminal GND to the output terminal OUT via the resistor 14c and the parasitic transistor Q2.
- the potential separation unit 14 sets the p-type well 12 and the ground terminal GND to the same potential when the output terminal OUT is at a higher potential than the ground terminal GND, and p when the output terminal OUT is at a lower potential than the ground terminal GND.
- the mold well 12 and the output terminal OUT work to have the same potential.
- the conventional structure in which the p-type well 12 is directly connected to the ground terminal GND (see the previous FIG. 9).
- the parasitic transistor Q1 does not turn on even when the n-type semiconductor substrate 11 is at a negative potential (OUT ⁇ GND). Accordingly, it is possible to prevent a voltage drop at the control terminal IN, and thus it is possible to maintain the normal operation of the semiconductor device 10.
- the p-type well 12 and the p-type well 14a are desirably arranged with a sufficient distance so that there is no conduction between them.
- an element isolation region (such as a collector wall or an insulating trench) may be disposed between the p-type well 12 and the p-type well 14a.
- the resistance value of the resistor 14c is appropriately adjusted to a necessary and sufficient size according to the current capability of the parasitic transistor Q2. More specifically, the resistance value of the resistor 14c may be set smaller as the current capability of the parasitic transistor Q2 is higher, and the resistance value of the resistor 14c may be set higher as the current capability of the parasitic transistor Q2 is lower. However, it should be noted that noise is easily superimposed on the node voltage GND_ref if the resistance value of the resistor 14c is set too large.
- FIG. 2 is an application diagram showing an application example to the low-side switch IC.
- the electronic apparatus 1 illustrated in the figure includes a semiconductor device 100, a microcomputer M1, an external load Z1, and a resistor R1.
- a control voltage Vg (for example, a rectangular wave voltage pulse-driven between 0 V and 5 V) is input from the microcomputer M1 to the control terminal IN via a resistor R1 (for example, several hundred ⁇ ).
- a load Z1 is externally connected between the output terminal OUT and the power supply line.
- the ground terminal GND is connected to the ground line.
- the output transistor 110 is connected between the output terminal OUT and the ground terminal GND, and is a low-side switch (NMOSFET in this figure) that conducts / cuts off between the load Z1 and the ground line according to the control voltage Vg.
- the drain of the output transistor 110 is connected to the output terminal OUT.
- the source and back gate of the output transistor 110 are both connected to the ground terminal GND.
- the output transistor 110 is turned on when the control voltage Vg is at a high level and turned off when the control voltage Vg is at a low level.
- the drain current Id corresponding to the on / off of the output transistor 110 flows.
- the direction flowing from the output terminal OUT to the ground terminal GND via the output transistor 110 is positive (Id> 0), and conversely, the output transistor from the ground terminal GND is output.
- the direction flowing toward the output terminal OUT via 110 is defined as negative (Id ⁇ 0).
- the drain voltage Vd of the output transistor 110 is a positive voltage (Vd> 0, that is, OUT> GND) when the positive drain current Id flows, and the negative voltage when the negative drain current Id flows. (Vd ⁇ 0, that is, OUT ⁇ GND).
- Vd ⁇ 0 that is, OUT ⁇ GND
- the drain voltage Vd may become a negative voltage.
- the potential separator 130 is connected between the p-type well 121 (see FIG. 3) in which the controller 120 is formed and the ground terminal GND, and when the output terminal OUT is at a higher potential than the ground terminal GND.
- the potential separation unit 130 corresponds to the potential separation unit 14 of FIG.
- control terminal IN and the gate of the output transistor 110 are directly connected, but the configuration of the semiconductor device 100 is not limited to this.
- a switch and a resistor that are turned off between the control terminal IN and the output transistor 110 until the control voltage Vg applied to the control terminal IN reaches a predetermined value. May be provided.
- the control terminal IN and the gate of the transistor 110 are different nodes, and the control voltage Vg applied to the control terminal IN and the gate voltage of the transistor 110 are also different voltages.
- FIG. 3 is a longitudinal sectional view schematically showing a first structural example of the semiconductor device 100.
- the semiconductor device 100 in this figure is formed by integrating an output transistor 110, a control unit 120, and a potential separation unit 130 on an n-type semiconductor substrate 101.
- the size (thickness, width, etc.) of each component may be different from the actual one.
- the n-type semiconductor substrate 101 includes an n-type substrate layer 101a as a base.
- An n-type epitaxial growth layer 101b is formed on the entire surface of the n-type substrate layer 101a.
- a substrate electrode 101c is formed on the entire back surface of the n-type substrate layer 101b.
- the substrate electrode 101 c is connected to the output terminal OUT as the drain of the output transistor 110.
- the n-type semiconductor substrate 101 corresponds to the n-type semiconductor substrate 11 in FIG.
- a p-type well 111 is formed in the n-type semiconductor substrate 101 in the formation region of the output transistor 110.
- a trench gate 112 extending from the surface to the n-type epitaxial growth layer 101b is formed.
- the inner wall surface of the trench gate 112 is covered with a gate oxide film, and the inside thereof is filled with gate polysilicon.
- a high-concentration n-type semiconductor region 113 is formed around the trench gate 112. Further, around the high-concentration n-type semiconductor region 113, a high-concentration p-type semiconductor region is formed.
- the high-concentration n-type semiconductor region 113 functions as a source
- the n-type semiconductor substrate 101 functions as a drain
- the trench gate 112 functions as a gate
- a p-type well 111 and its The high-concentration p-type semiconductor region 114) corresponding to the contact functions as a back gate.
- the output transistor 110 is formed of a single cell.
- the structure of the output transistor 110 is not limited to this, and a large number of unit cells are arranged in parallel.
- One output transistor 110 may be formed by connection.
- the unit cell can be miniaturized, so that the on-resistance (several tens of m ⁇ ) of the output transistor 110 can be realized.
- a p-type well 121 is formed in the n-type semiconductor substrate 101 in the formation region of the control unit 120.
- a low-concentration n-type semiconductor region 122, a low-concentration p-type semiconductor region 123, and a high-concentration p-type semiconductor region 124 are formed in the p-type well 121.
- a high concentration n-type semiconductor region 125 is formed in the low concentration n-type semiconductor region 122.
- a high concentration n-type semiconductor region 126 and a high concentration p-type semiconductor region 127 are formed. Both the high-concentration n-type semiconductor regions 125 and 126 are connected to the control terminal IN.
- the high-concentration p-type semiconductor region 124 and the high-concentration p-type semiconductor region 127 are both connected to the ground terminal GND through the resistor 135.
- constituent elements 121 to 127 are obtained by extracting only the part corresponding to the basic structure of FIG. 1 from among the plurality of constituent elements forming the control unit 120. More specifically, the p-type well 121 (and the high-concentration p-type semiconductor region 124 corresponding to its contact) corresponds to the p-type well 12 in FIG. The same applies to the low-concentration p-type semiconductor region 123 (and the high-concentration p-type semiconductor region 124 corresponding to the contact thereof). On the other hand, the low-concentration n-type semiconductor region 122 (and the high-concentration n-type semiconductor region 125 corresponding to its contact) corresponds to the n-type semiconductor region 13 in FIG. The high concentration n-type semiconductor region 126 is also the same.
- both the p-type well 12 and the n-type semiconductor region 13 in FIG. 1 are mounted as components of the control unit 120.
- a p-type well 131 is formed in the n-type semiconductor substrate 101 in the formation region of the potential separation unit 130.
- a low-concentration n-type semiconductor region 132 and a high-concentration p-type semiconductor region 133 are formed in the p-type well 131.
- a high concentration n-type semiconductor region 134 is formed in the low concentration n-type semiconductor region 132.
- the high concentration p-type semiconductor region 133 is directly connected to the ground terminal GND.
- the high-concentration n-type semiconductor region 134 is connected to the ground terminal GND through the resistor 135.
- constituent elements 131 to 135 are obtained by extracting only the part corresponding to the basic structure of FIG. 1 from among the plurality of constituent elements forming the potential separating unit 130. More specifically, the p-type well 131 (and the high-concentration p-type semiconductor region 133 corresponding to the contact thereof) corresponds to the p-type well 14a in FIG. On the other hand, the low-concentration n-type semiconductor region 132 (and the high-concentration n-type semiconductor region 134 corresponding to the contact thereof) corresponds to the n-type semiconductor region 14b in FIG. The resistor 135 corresponds to the resistor 14c in FIG.
- the semiconductor device 100 of this figure is accompanied by parasitic transistors Q11 and Q12 as in the above-described basic structure (FIG. 1).
- the parasitic transistor Q11 is an npn-type bipolar transistor having an n-type semiconductor substrate 101 as an emitter, a p-type well 121 as a base, and a low-concentration n-type semiconductor region 122 as a collector.
- the parasitic transistor Q12 is an npn-type bipolar transistor having an n-type semiconductor substrate 101 as an emitter, a p-type well 131 as a base, and a low-concentration n-type semiconductor region 132 as a collector.
- the parasitic transistor Q12 is not turned on because the base-emitter of the parasitic transistor Q12 is reverse-biased. Therefore, the current I12 does not flow in the path from the ground terminal GND to the output terminal OUT via the resistor 135 and the parasitic transistor Q12.
- the base-emitter of the parasitic transistor Q11 is also reverse-biased. Accordingly, since the parasitic transistor Q11 is not turned on, the current I11 does not flow in the path from the control terminal IN to the output terminal OUT via the parasitic transistor Q11.
- the potential separator 130 sets the p-type well 121 and the ground terminal GND to the same potential when the output terminal OUT is higher in potential than the ground terminal GND, and outputs the same.
- the terminal OUT is at a lower potential than the ground terminal GND, the p-type well 121 and the output terminal OUT work to have the same potential.
- FIG. 4 is a waveform diagram showing the behavior of the semiconductor device 100 at the time of negative output (OUT ⁇ GND), in which the control voltage Vg, the drain voltage Vd, and the drain current Id are depicted in order from the top.
- the control voltage Vg the solid line indicates the behavior when the potential separator 130 is provided, and the broken line indicates the behavior when the potential separator 130 is not provided.
- the drain voltage Vd becomes a negative voltage.
- the potential separation unit 130 is not provided, a current I11 flows through a path from the control terminal IN to the output terminal OUT via the parasitic transistor Q11.
- the microcomputer M1 connected to the control terminal IN generally has a low drive capability (current capability) of the control voltage Vg. Therefore, when the current I11 is drawn from the control terminal IN via the parasitic transistor Q11, the control voltage Vg is greatly reduced, which may hinder the operation of the semiconductor device 100.
- the semiconductor device 100 can be applied to any application in which the output terminal OUT can be at a lower potential than the ground terminal GND. Degree) can be increased.
- the DC current amplification factor hFE of the parasitic transistor Q11 has a positive temperature characteristic, so that the higher the temperature Ta, the easier the large current I11 flows and the control voltage Vg tends to decrease.
- the parasitic transistor Q11 is turned on by the potential separation unit 130. It can be said that the prevention function becomes extremely important.
- FIG. 5 is a circuit diagram showing a specific example of the control unit 120 and the potential separation unit 130.
- the control unit 120 of this configuration example includes a PMOSFET 210, an NMOSFET 220, resistors 230 and 240, and a comparator 250.
- the source and back gate of the PMOSFET 210 are both connected to the control terminal IN.
- the drain of the PMOSFET 210 and the drain of the NMOSFET 220 are both connected to the output terminal of the output signal S2.
- the source of the NMOSFET 220 is directly connected to the ground terminal GND.
- the back gate of the NMOSFET 220 is connected to the ground terminal GND through the potential separator 130.
- the comparator 250 operates using the control voltage Vg as a power source, and compares the divided voltage V1 input to the non-inverting input terminal (+) with a predetermined threshold voltage V2 input to the inverting input terminal ( ⁇ ), The comparison signal S1 is output.
- the comparison signal S1 is at a low level when the divided voltage V1 is lower than the threshold voltage V2, and is at a high level when the divided voltage V1 is higher than the threshold voltage V2.
- the output signal S2 can be used as, for example, a power-on reset signal for an internal circuit included in the semiconductor device 100.
- the potential separation unit 130 of this configuration example includes a resistor 135 and a PMOSFET 136 formed in the p-type well 131.
- the p-type well 131 and the second end of the resistor 135 are both connected to the ground terminal GND.
- FIG. 6 is a longitudinal sectional view schematically showing a second structural example of the semiconductor device 100.
- an example of the vertical structure when the specific components (PMOSFET 210 and NMOSFET 220 and dummy PMOSFET 136) of FIG. 5 are mounted is depicted based on the above-described first structure example (FIG. 3). . Therefore, the same components as those in the first structural example are denoted by the same reference numerals as those in FIG. 3, and redundant description is omitted.
- the characteristic portions of the second structural example are mainly described. To do.
- the control unit 120 will be described.
- the PMOSFET 210 is formed in the low concentration n-type semiconductor region 122. More specifically, in the low-concentration n-type semiconductor region 122, in addition to the high-concentration n-type semiconductor region 125, high-concentration p-type semiconductor regions 210S and 210D are formed.
- a gate electrode 210G is formed on the channel region sandwiched between the high concentration p-type semiconductor region 210S and the high concentration p-type semiconductor region 210D.
- the high-concentration p-type semiconductor region 210S corresponds to the source of the PMOSFET 210 and is connected to the control terminal IN.
- the high concentration p-type semiconductor region 210D corresponds to the drain of the PMOSFET 210 and is connected to the application terminal of the output signal S2.
- the gate electrode 210G is connected to the application terminal for the comparison signal S1.
- the low concentration n-type semiconductor region 122 corresponds to the back gate of the PMOSFET 210 and is connected to the control terminal IN through the high concentration n-type semiconductor region 125.
- an NMOSFET 220 is formed in the low concentration p-type semiconductor region 123. More specifically, in the low-concentration p-type semiconductor region 123, high-concentration n-type semiconductor regions 220D and 220S are formed in addition to the above-described high-concentration p-type semiconductor region 127.
- a gate electrode 220G is formed on the channel region sandwiched between the high concentration n-type semiconductor region 220D and the high concentration n-type semiconductor region 220S.
- the high concentration n-type semiconductor region 220D corresponds to the drain of the NMOSFET 220 and is connected to the application terminal of the output signal S2.
- the high concentration n-type semiconductor region 220S corresponds to the source of the NMOSFET 220 and is connected to the ground terminal GND.
- the gate electrode 220G is connected to the application terminal for the comparison signal S1.
- the low-concentration p-type semiconductor region 123 (and the p-type well 121 having the same potential as this) corresponds to the back gate of the NMOSFET 220 and is connected to the application terminal of the node voltage GND_ref via the high-concentration p-type semiconductor regions 127 and 124. ing.
- the high-concentration p-type semiconductor region 124 corresponding to the contact of the p-type well 121 is formed on the peripheral portion of the p-type well 121 so as to surround the low-concentration n-type semiconductor region 122 and the low-concentration p-type semiconductor region 123. It is desirable to provide a plurality.
- a dummy PMOSFET 136 is formed in the low-concentration n-type semiconductor region 132 in the formation region of the potential separation unit 130. More specifically, in the low-concentration n-type semiconductor region 132, in addition to the above-described high-concentration n-type semiconductor region 134, high-concentration p-type semiconductor regions 136S and 136D are formed. A gate electrode 136G is formed on the channel region sandwiched between the high concentration p-type semiconductor region 136S and the high concentration p-type semiconductor region 136D.
- the high concentration p-type semiconductor regions 136S and 136D correspond to the source and drain of the dummy PMOSFET 136, respectively.
- the low-concentration n-type semiconductor region 132 (and the high-concentration n-type semiconductor region 134 that is the contact) corresponds to the back gate of the dummy PMOSFET 136.
- the high-concentration p-type semiconductor regions 136S and 136D, the high-concentration n-type semiconductor region 134, and the gate electrode 136G are all connected to the ground terminal GND through a common resistor 135. That is, the dummy PMOSFET 136 does not function as a transistor because all of its terminals are short-circuited.
- the back gate of the dummy PMOSFET 136 is used as the low-concentration n-type semiconductor region 132, a special element formation process is not required for mounting the potential separation unit 130, and the PMOSFET formation process is used as it is. can do.
- the potential separator 130 is not different from the first structure example.
- the p-type well 121 and the ground terminal GND are used.
- the output terminal OUT is at a lower potential than the ground terminal GND, the p-type well 121 and the output terminal OUT work to have the same potential.
- the parasitic transistor Q11 is not turned on, so that it is possible to prevent a voltage drop at the control terminal IN, and thus the normal operation of the semiconductor device 100 is maintained. It becomes possible to do.
- FIG. 7 is a circuit diagram showing a modification of the potential separation unit 130.
- the potential separation unit 130 of the present modification is basically the same as the configuration of FIG. 5, but is characterized in that a resistor 135 is externally attached. More specifically, the semiconductor device 100 has a resistance connection terminal EX for externally attaching a resistor 135, and the resistor 135 is externally connected between the resistance connection terminal EX and the ground terminal GND. Yes.
- the resistance connection terminal EX is connected to the application terminal of the node voltage GND_ref in the semiconductor device 100.
- the method for adjusting the resistance value is not necessarily limited to this, and for example, the resistance value of the resistor 135 incorporated in the semiconductor device 100 can be appropriately adjusted by laser trimming or the like.
- FIG. 8 is an external view showing a configuration example of the vehicle X.
- the vehicle X of this configuration example includes a battery (not shown) and various electronic devices X11 to X18 that operate by receiving power supply from the battery. Note that the mounting positions of the electronic devices X11 to X18 in this figure may differ from actual ones for convenience of illustration.
- the electronic device X11 is an engine control unit that performs control related to the engine (injection control, electronic throttle control, idling control, oxygen sensor heater control, auto cruise control, etc.).
- the electronic device X12 is a lamp control unit that controls turning on and off such as HID [high intensity discharged lamp] and DRL [daytime running lamp].
- the electronic device X13 is a transmission control unit that performs control related to the transmission.
- the electronic device X14 is a body control unit that performs control (ABS [anti-lock brake system] control, EPS [electric power steering] control, electronic suspension control, etc.) related to the movement of the vehicle X.
- control ABS [anti-lock brake system] control, EPS [electric power steering] control, electronic suspension control, etc.
- the electronic device X15 is a security control unit that performs drive control such as door locks and security alarms.
- the electronic device X16 is an electronic device that is built into the vehicle X at the factory shipment stage as a standard equipment item or manufacturer's option product, such as a wiper, an electric door mirror, a power window, a damper (shock absorber), an electric sunroof, and an electric seat. It is.
- the electronic device X17 is an electronic device that is optionally mounted on the vehicle X as a user option product, such as an in-vehicle A / V [audio / visual] device, a car navigation system, and an ETC [electronic toll collection system].
- a user option product such as an in-vehicle A / V [audio / visual] device, a car navigation system, and an ETC [electronic toll collection system].
- the electronic device X18 is an electronic device equipped with a high-voltage motor such as an in-vehicle blower, an oil pump, a water pump, or a battery cooling fan.
- a high-voltage motor such as an in-vehicle blower, an oil pump, a water pump, or a battery cooling fan.
- semiconductor devices 10 and 100 described above can be incorporated into any of the electronic devices X11 to X18.
- the invention disclosed in this specification can be used for all semiconductor devices (low-side switch IC, switching power supply IC, motor driver IC, etc.) to which a negative voltage can be applied to an n-type semiconductor substrate. It is.
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Abstract
Description
図1は、半導体装置の基本構造(発明の理解に必要となる最小限の構成要素のみ)を模式的に示す縦断面図である。本図の半導体装置10は、出力端子OUTに接続されたn型半導体基板11と、n型半導体基板11に形成されたp型ウェル12と、p型ウェル12に形成されて制御端子INに接続されたn型半導体領域13と、p型ウェル12と接地端子GNDとの間に接続された電位分離部14と、を有する。
図2は、ローサイドスイッチICへの適用例を示すアプリケーション図である。本図に例示した電子機器1は、半導体装置100と、これに外付けされるマイコンM1、負荷Z1、及び、抵抗R1を有する。
図8は、車両Xの一構成例を示す外観図である。本構成例の車両Xは、不図示のバッテリと、バッテリから電力の供給を受けて動作する種々の電子機器X11~X18と、を搭載している。なお、本図における電子機器X11~X18の搭載位置については、図示の便宜上、実際とは異なる場合がある。
なお、本明細書中に開示されている種々の技術的特徴は、上記実施形態のほか、その技術的創作の主旨を逸脱しない範囲で種々の変更を加えることが可能である。すなわち、上記実施形態は、全ての点で例示であって制限的なものではないと考えられるべきであり、本発明の技術的範囲は、上記実施形態の説明ではなく、特許請求の範囲によって示されるものであり、特許請求の範囲と均等の意味及び範囲内に属する全ての変更が含まれると理解されるべきである。
10 半導体装置
11 n型半導体基板
12 p型ウェル
13 n型半導体領域
14 電位分離部
14a p型ウェル
14b n型半導体領域
14c 抵抗
100 半導体装置
101 n型半導体基板
101a n型基板層
101b n型エピタキシャル成長層
101c 基板電極
110 出力トランジスタ
111 p型ウェル
112 トレンチゲート
113 高濃度n型半導体領域
114 高濃度p型半導体領域
120 制御部
121 p型ウェル
122 低濃度n型半導体領域
123 低濃度p型半導体領域
124、127 高濃度p型半導体領域
125、126 高濃度n型半導体領域
130 電位分離部
131 p型ウェル
132 低濃度n型半導体領域
133 高濃度p型半導体領域
134 高濃度n型半導体領域
135 抵抗
136 ダミーPMOSFET
136S 高濃度p型半導体領域(ソース)
136D 高濃度p型半導体領域(ドレイン)
136G ゲート電極(ゲート)
210 PMOSFET
210S 高濃度p型半導体領域(ソース)
210D 高濃度p型半導体領域(ドレイン)
210G ゲート電極(ゲート)
220 NMOSFET
220S 高濃度n型半導体領域(ソース)
220D 高濃度n型半導体領域(ドレイン)
220G ゲート電極(ゲート)
230 コンパレータ
240、250 抵抗
IN 制御端子
OUT 出力端子(負荷接続端子)
GND 接地端子
EX 抵抗接続端子
Q1、Q2、Q11、Q12 寄生トランジスタ
M1 マイコン
R1 抵抗
Z1 負荷
X 車両
X11~X18 電子機器
Claims (11)
- 出力端子に接続されたn型半導体基板と、
前記n型半導体基板に形成された第1p型ウェルと、
前記第1p型ウェルに形成されて制御端子に接続された第1n型半導体領域と、
前記第1p型ウェルと接地端子との間に接続された電位分離部と、
を有し、
前記電位分離部は、前記出力端子が前記接地端子よりも高電位であるときには前記第1p型ウェルと前記接地端子を同電位とし、前記出力端子が前記接地端子よりも低電位であるときには前記第1p型ウェルと前記出力端子を同電位とする、
ことを特徴とする半導体装置。 - 前記電位分離部は、
前記n型半導体基板に形成されて前記接地端子に接続された第2p型ウェルと、
前記第2p型ウェルに形成された第2n型半導体領域と、
を有し、
前記第1p型ウェルと前記第2n型半導体領域は、共通の抵抗を介して前記接地端子に接続されている、
ことを特徴とする請求項1に記載の半導体装置。 - 出力端子に接続されたn型半導体基板と、
前記n型半導体基板に形成された第1p型ウェルと、
前記第1p型ウェルに形成されて制御端子に接続された第1n型半導体領域と、
前記第1p型ウェルと接地端子との間に接続された電位分離部と、
を有し、
前記電位分離部は、
前記n型半導体基板に形成されて前記接地端子に接続された第2p型ウェルと、
前記第2p型ウェルに形成された第2n型半導体領域と、
を有し、
前記第1p型ウェルと前記第2n型半導体領域は、共通の抵抗を介して前記接地端子に接続されている、
ことを特徴とする半導体装置。 - 前記抵抗を外付けするための外部端子をさらに有することを特徴とする請求項2または請求項3に記載の半導体装置。
- 前記第2n型半導体領域は、前記第2p型ウェルに形成されたダミーPMOSFETのバックゲートに相当することを特徴とする請求項2~請求項4のいずれか一項に記載の半導体装置。
- 前記出力端子と前記接地端子との間に接続されており前記制御端子から入力される制御電圧に応じてオン/オフされる縦型構造の出力トランジスタと、
前記制御電圧を電源として動作する制御部と、
をさらに有し、
前記第1p型ウェルと前記第1n型半導体領域は、いずれも前記制御部の構成要素であることを特徴とする請求項1~請求項5のいずれか一項に記載の半導体装置。 - 前記制御部は、
前記制御端子と前記出力トランジスタのゲートとの間に接続されたPMOSFETと、
前記出力トランジスタのゲートと前記接地端子との間に接続されたNMOSFETと、
を含み、
前記第1p型ウェルは、前記NMOSFETのバックゲートに相当し、
前記第1n型半導体領域は、前記PMOSFETのバックゲートに相当する、
ことを特徴とする請求項6に記載の半導体装置。 - 請求項1~請求項7のいずれか一項に記載の半導体装置と、
前記半導体装置の制御端子に制御電圧を供給するマイコンと、
前記半導体装置の出力端子に外付けされる負荷と、
を有することを特徴とする電子機器。 - 前記負荷は、誘導性負荷であることを特徴とする請求項8に記載の電子機器。
- 前記半導体装置は、ローサイドスイッチIC、スイッチング電源IC、または、モータドライバICであることを特徴とする請求項9に記載の電子機器。
- 請求項10に記載の電子機器と、
前記電子機器に電力を供給するバッテリと、
を有することを特徴とする車両。
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JP2012243930A (ja) * | 2011-05-19 | 2012-12-10 | Renesas Electronics Corp | 半導体装置、半導体パッケージ、および半導体装置の製造方法 |
JP2013093448A (ja) * | 2011-10-26 | 2013-05-16 | Mitsubishi Electric Corp | 半導体装置 |
JP2015053300A (ja) * | 2013-09-05 | 2015-03-19 | 富士電機株式会社 | 半導体装置 |
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Cited By (3)
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JP2019145945A (ja) * | 2018-02-19 | 2019-08-29 | ローム株式会社 | スイッチ装置 |
JP7185405B2 (ja) | 2018-02-19 | 2022-12-07 | ローム株式会社 | スイッチ装置 |
WO2024084833A1 (ja) * | 2022-10-19 | 2024-04-25 | ローム株式会社 | 半導体装置、電子機器、車両 |
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EP3382750A4 (en) | 2019-07-03 |
JP6498787B2 (ja) | 2019-04-10 |
EP3382750B1 (en) | 2020-10-14 |
JPWO2017115553A1 (ja) | 2018-11-08 |
CN108431945B (zh) | 2022-06-10 |
US10692774B2 (en) | 2020-06-23 |
CN108431945A (zh) | 2018-08-21 |
EP3382750A1 (en) | 2018-10-03 |
US20190006246A1 (en) | 2019-01-03 |
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