Patent Grant
11569030
The semiconductor integrated circuit (IC) industry has experienced rapid growth. In the course of IC evolution, functional density (i.e., the number of interconnected devices per chip area) has generally increased while geometry size (i.e., the smallest component (or line) that can be created using a fabrication process) has decreased. This scaling down process generally provides benefits by increasing production efficiency and lowering associated costs. Such scaling down has also increased the complexity of an IC. In some applications, an IC includes electrical components, such as a voltage regulator, that the operations thereof are sometimes based on measuring their currents.
Aspects of the present disclosure are best understood from the following detailed description when read with the accompanying figures. It is noted that, in accordance with the standard practice in the industry, various features are not drawn to scale. In fact, the dimensions of the various features may be arbitrarily increased or reduced for clarity of discussion.
The following disclosure provides many different embodiments, or examples, for implementing different features of the invention. Specific examples of components and arrangements are described below to simplify the present disclosure. These are, of course, merely examples and are not intended to be limiting. For example, the formation of a first feature over or on a second feature in the description that follows may include embodiments in which the first and second features are formed in direct contact, and may also include embodiments in which additional features may be formed between the first and second features, such that the first and second features may not be in direct contact. In addition, the present disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.
Further, spatially relative terms, such as “beneath,” “below,” “lower,” “above,” “upper” and the like, may be used herein for ease of description to describe one element or feature's relationship to another element(s) or feature(s) as illustrated in the figures. The spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. The apparatus may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein may likewise be interpreted accordingly.
Certain applications, such as voltage regulators, use high speed and accurate in-situ current measurements. This disclosure, in various embodiments, presents several methods of implementing an on-die transformer-based current sensor.
In various applications, voltage regulators rely on voltage feedback or current feedback in order to implement the control loop for high speed and high accuracy regulation. In some embodiments, it is desirable for voltage regulators to have as fast as possible control loop in order to respond to transient events in the minimum time. In some embodiments, current feedback provides a faster response than voltage feedback.
The present disclosure describes various embodiments of measuring current values in an integrated circuit. In some embodiments, performing transformer-based current sensing operations is provided. In some embodiments, current in the primary path (e.g., an electrical path in an output stage) is magnetically coupled with a sense stage. An alternating current (AC) component of the current is magnetically coupled and measured. One possible application is to measure a current value for a switched regulator, where a half-bridge rectifier thereof produces an AC current on a switching side of an inductor of the switched regulator. In some embodiments, an output current value of the switched regulator is also determinable based on the measured current value of the AC current on the switching side of the inductor.
First conductive path 110 extends along an X direction. First conductive path 110 includes a first conductive line 112 under ferromagnetic structure 140, a second conductive line 114 over ferromagnetic structure 140, and a via plug 116 connecting first conductive line 112 and second conductive line 114. In some embodiments, via plug 116 is coplanar with ferromagnetic structure 140. In some embodiments, first conductive path 110 is configured to carry a first time-varying current I1 and to generate a first time-varying magnetic field B1 based on first time-varying current I1.
Second conductive path 120 extends along X direction. Second conductive path 120 includes a first conductive line 122 under ferromagnetic structure 140, a second conductive line 124 over ferromagnetic structure 140, and a via plug 126 connecting first conductive line 122 and second conductive line 124. In some embodiments, via plug 126 is coplanar with ferromagnetic structure 140. In some embodiments, second conductive path 120 is configured to carry a second time-varying current I2 and to generate a second time-varying magnetic field B2 based on second time-varying current I2.
Two conductive paths 110 and 120 are explained as an example. In some embodiments, one of conductive paths 110 and 120 is omitted, and only the current on the remaining conductive path is measured. In some embodiments, three or more conductive paths are arranged in a manner similar to conductive paths 110 and 120, and the current values of the three or more conductive paths are measured based on their corresponding magnetic fields.
Ferromagnetic structure 140 comprises a ferromagnetic ring having four portions 140a, 140b, 140c, and 140d. Portions 140a and 140b of ferromagnetic structure 140 extend along a direction Y different from direction X, and portions 140c and 140d of ferromagnetic structure 140 extend along direction X. In some embodiments, ferromagnetic structure 140 has a magnetic permeability higher than a magnetic permeability of free-space or a magnetic permeability of a dielectric material (e.g., material 442 or passivation layer 430 in
Coil structure 130 is wrapped around portion 140d of ferromagnetic structure 140 by a predetermined number of turns. For example, in some embodiments, coil structure 130 in
Coil structure 130 has a first end 136 and a second end 138. Coil structure 130 is magnetically coupled with the first conductive path 110 and/or second conductive path 120 through the first time-varying magnetic field B1 and/or second time-varying magnetic field B2. Coil structure 130 is configured to generate an induced electrical potential responsive to the first time-varying magnetic field B1 and/or second time-varying magnetic field B2. The voltage level of the induced electrical potential is measurable from the ends 136 and 138 of coil structure 130.
Voltage sensing circuit 150 is electrically coupled with the ends 136 and 138 of coil structure 130 and is configured to measure the voltage level of the induced electrical potential of coil structure 130. The measurement result is output as signal VSENSE. Based on the phases or directions of current I1 and current I2 and Ampere's right-hand rule, first time-varying magnetic field B1 and second time-varying magnetic field B2 are superposed, as observed by the coil structure 130, in an additive manner or a subtractive manner. For example, if current I1 and current I2 are arranged in a same direction and do not have a phase offset, then the first time-varying magnetic field B1 and the second time-varying magnetic field B2, as observed by the coil structure 130, are additive and signal VSENSE is usable to measure an amplitude of current (I1+I2). For example, if current I1 and current I2 are arranged in an opposite direction and do not have a phase offset, then the first time-varying magnetic field B1 and the second time-varying magnetic field B2, as observed by the coil structure 130, are subtractive and signal VSENSE is usable to measure an amplitude of current (I1−I2). Therefore, depending on the configuration of conductive paths 110 and 120, signal VSENSE is usable to measure an amplitude of (I1+I2) or (I1−I2).
In some embodiments, voltage sensing circuit 150 is in the integrated circuit 100 on which the conductive path 110 and/or 120 and coil structure 130 are formed. In some embodiments, voltage sensing circuit 150 is outside the integrated circuit 100.
In some embodiments, integrated circuit 100 includes a first interconnection layer (e.g., one of the plurality of interconnection layers 420 in
In some embodiments, the first plurality of conductive lines 132 is in first interconnection layer 420, and the second plurality of conductive lines 134 is in the second interconnection layer 450. The first plurality of conductive lines 132 and the second plurality of conductive lines 134 are connected through corresponding via plugs.
In some embodiments, the first conductive line 112 of first conductive path 110 is in the first interconnection layer 420. In some embodiments, the second conductive line 114 of first conductive path 110 is in the second interconnection layer 450. In some embodiments, the first conductive line 122 of second conductive path 120 is in the first interconnection layer 420. In some embodiments, the second conductive line 124 of second conductive path 120 is in the second interconnection layer 450. In some embodiments, the second conductive line 114 of first conductive path 110 is a bond wire (e.g., bond wire 460 in
First conductive path 210 extends along an X direction. First conductive path 210 is under ferromagnetic structure 240. In some embodiments, first conductive path 210 is over ferromagnetic structure 240. In some embodiments, first conductive path 210 is configured to carry a first time-varying current I1 and to generate a first time-varying magnetic field B1 based on first time-varying current I1.
Second conductive path 220 extends along X direction. Second conductive path 220 is over ferromagnetic structure 240. In some embodiments, second conductive path 220 is under ferromagnetic structure 240. In some embodiments, second conductive path 220 is configured to carry a second time-varying current I2 and to generate a second time-varying magnetic field B2 based on second time-varying current I2.
Two conductive paths 210 and 220 are explained as an example. In some embodiments, one of conductive paths 210 and 220 is omitted. In some embodiments, three or more conductive paths are arranged in a manner similar to conductive paths 210 and 220, and the current values of the three or more conductive paths are measured based on their corresponding magnetic fields.
Ferromagnetic structure 240 comprises a ferromagnetic strip extending along a Y direction. In some embodiments, ferromagnetic structure 240 has a magnetic permeability higher than a magnetic permeability of free-space or a magnetic permeability of a dielectric material (e.g., material 442 or passivation layer 430 in
Based on the phases or directions of current I1 and current I2 and the Ampere's right-hand rule, first time-varying magnetic field B1 and second time-varying magnetic field B2 are superposed, as observed by the coil structure 130, in an additive manner or a subtractive manner. For example, if current I1 and current I2 are arranged in a same direction and do not have a phase offset, then the first time-varying magnetic field B1 and the second time-varying magnetic field B2, as observed by the coil structure 130, are additive and signal VSENSE is usable to measure an amplitude of current (I1+I2). For example, if current I1 and current I2 are arranged in an opposite direction and do not have a phase offset, then the first time-varying magnetic field B1 and the second time-varying magnetic field B2, as observed by the coil structure 130, are subtractive and signal VSENSE is usable to measure an amplitude of current (I1−I2). Therefore, depending on the configuration of conductive paths 210 and 220, signal VSENSE is usable to measure an amplitude of (I1+I2) or (I1−I2).
In some embodiments, integrated circuit 200 includes a first interconnection layer (e.g., one of the plurality of interconnection layers 420 in
In some embodiments, the first conductive path 210 is in first interconnection layer 420. In some embodiments, the second conductive path 220 is in second interconnection layer 450. In some embodiments, the second conductive path 220 is a bond wire (e.g., bond wire 460 in
First conductive path 310 extends along an X direction. In some embodiments, first conductive path 310 is configured to carry a first time-varying current I1 and to generate a first time-varying magnetic field B1 based on first time-varying current I1. Second conductive path 320 extends along X direction. In some embodiments, second conductive path 320 is configured to carry a second time-varying current I2 and to generate a second time-varying magnetic field B2 based on second time-varying current I2. In some embodiments, conductive paths 310 and 320 are in the same interconnection layer (e.g., one of the plurality of interconnection layers 420 or 450 in
Two conductive paths 310 and 320 are explained as an example. In some embodiments, one of conductive paths 310 and 320 is omitted. In some embodiments, three or more conductive paths are arranged in a manner similar to conductive paths 310 and 320, and the current values of the three or more conductive paths are measured based on their corresponding magnetic fields.
Coil structure 330 includes a spiral coil 332 in a first interconnection layer 420 and a connecting line 334 in a second interconnection layer 450. In some embodiments, spiral coil 332 is in a second interconnection layer 450 and the connecting line is in the first interconnection layer 420. In some embodiments, spiral coil 332 is coplanar with one or both of conductive paths 310 and 320. In some embodiments, spiral coil 332 is not coplanar with conductive paths 310 and 320. Spiral coil 332 includes a plurality of conductors 340 connected to each other in a winding configuration. In some embodiments, at least one conductor of the plurality of conductors 340 is coplanar with at least one conductor of the plurality of conductors 340. In some embodiments, at least one conductor of the plurality of conductors 340 is not coplanar with at least one conductor of the plurality of conductors 340.
Coil structure 330 is magnetically coupled with the first conductive path 310 and/or second conductive path 320 through the first time-varying magnetic field B1 and/or second time-varying magnetic field B2. Coil structure 330 is configured to generate an induced electrical potential responsive to the first time-varying magnetic field B1 and/or second time-varying magnetic field B2. The voltage level of the induced electrical potential is measurable from the ends 336 and 338 of coil structure 330.
Based on the phases or directions of current I1 and current I2 and the Ampere's right-hand rule, first time-varying magnetic field B1 and second time-varying magnetic field B2 are superposed, as observed by the coil structure 330, in an additive manner or a subtractive manner. Therefore, depending on the configuration of conductive paths 310 and 320, signal VSENSE is usable to measure an amplitude of (I1+I2) or (I1−I2).
Integrated circuit 400 includes a substrate 410, a plurality of interconnection layers 420 over substrate 410, a passivation layer 430 over the plurality of interconnection layers 420, a ferromagnetic structure 440 over passivation layer 430 and surrounded by material 442, a post-passivation interconnection layer 450 over passivation layer 430, and a bond wire 460 over post-passivation interconnection layer 450. In some embodiments, bond wire 460 is not used. In some embodiments, bond wire 460 is connected to post-passivation interconnection layer 450 by a ball bond 470. In some embodiments, ferromagnetic structure 440 is at least partially embedded in passivation layer 430. In some embodiments, material 442 is a dielectric material. In some embodiments, material 442 is an extended portion of passivation layer 430. The above-described structure is an example configuration, and other arrangements among elements of the integrated circuit 400 are within the contemplated scope of the present disclosure. In some embodiments, bond wire 460 or ball bond 470 is substituted with any other suitable configurations. For example, in some embodiments, wedge bonding or compliant bonding are substituted for ball bond 470. In some embodiments, integrated circuit 400 has a different combination or ordering of layers than the configuration shown in
In some embodiments, ferromagnetic structure 440 has a magnetic permeability higher than a magnetic permeability of free-space or a magnetic permeability of a dielectric material 442 adjacent to ferromagnetic structure 440. In some embodiments, ferromagnetic structure 440 has a material including cobalt, zirconium, or tantalum, or other suitable materials. In some embodiments, ferromagnetic structure 440 includes an alloy of cobalt, zirconium, and tantalum or other suitable materials. In some embodiments, ferromagnetic structure 440 corresponds to ferromagnetic structure 140, 240.
Integrated circuit 400 includes one or more electrical components 412 formed on substrate 410. In some embodiments, voltage sensing circuit 150 is formed by the one or more electrical components 412.
The method 500 begins with operation 510, where a time-varying magnetic field, such as magnetic field B1 or B2, is generated based on a time-varying current, such as I1 or I2, on a conductive path of the integrated circuit.
The method 500 proceeds to operation 520, where a portion of the time-varying magnetic field, such as magnetic field B1 or B2, is directed to pass through a coil structure 130 by a ferromagnetic structure 140. In some embodiments, when ferromagnetic structure 140 is omitted, operation 520 is omitted.
The method 500 proceeds to operation 530, where an induced electrical potential is generated by the coil structure 130 responsive to the magnetic field, such as magnetic field B1 or B2. The coil structure 130 is magnetically coupled with the conductive path through at least a portion of the time-varying magnetic field.
The method 500 proceeds to operation 540, where a voltage level of the induced electrical potential is measured by a voltage sensing circuit 150. The voltage sensing circuit 150 is electrically coupled with the coil structure 130.
Control circuit 610 is configured to output a first supply voltage VDD, a second supply voltage VSS, and a control signal to high-side driver 622 and low-side driver 624. High-side driver 622 is a PMOS transistor, and low-side driver 624 is an NMOS transistor. A source of high-side driver 622 is configured to receive voltage VDD, A source of low-side driver 624 is configured to receive voltage VSS, and drains of high-side driver 622 and low-side driver 624 are coupled together. Gates of high-side driver 622 and low-side driver 624 are coupled together and configured to receive control signal CRTL.
Inductor 630 is coupled between output node 650 and the drains of high-side driver 622 and low-side driver 624. Decoupling capacitor 640 is electrically coupled between output node 650 and ground GND. In operation, high-side driver 622 and low-side driver 624 are alternatively turned on to draw current IP from voltage VDD or current IN from voltage VSS. Current IOUT is thus the combination of current IP and current IN.
At time T1, low-side driver 624 is turned on and high-side driver 622 is turned off. Current IP is zero, and current IN transitions from zero to IH. During the time period from time T1 to time T2, low-side driver 624 remains turned on and high-side driver 622 remains turned off. Current IP remains zero, and current IN gradually decreases to IL, because the drains of high-side driver 622 and low-side driver 624 are electrically coupled with voltage VSS, which is lower than a predetermined output voltage at output node 650.
At time T2, high-side driver 622 is turned on and low-side driver 624 is turned off. Current IN is zero, and current IP transitions from zero to IL. During the time period from time T2 to time T3, high-side driver 622 remains turned on and low-side driver 624 remains turned off. Current IN remains zero, and current IP gradually increases to IH, because the drains of high-side driver 622 and low-side driver 624 are electrically coupled with voltage VDD, which is higher than the predetermined output voltage at output node 650.
The operation of circuit 600 at time T3 and T5 is similar to that at time T1, and detailed description thereof is thus omitted. The operation of circuit 600 at time T4 and T6 is similar to that at time T2, and detailed description thereof is thus omitted.
In some embodiments, by measuring current IP and/or current IN using the circuit as illustrated in any of
In accordance with one embodiment, an integrated circuit includes a first conductive path over a substrate, the first conductive path being configured to carry a first time-varying current and to generate a first time-varying magnetic field based on the first time-varying current. In some embodiments, the integrated circuit further includes a second conductive path over the substrate, the second conductive path being configured to carry a second time-varying current and to generate a second time-varying magnetic field based on the second time-varying current. In some embodiments, the integrated circuit further includes a coil structure over the substrate, the coil structure being magnetically coupled with the first conductive path and the second conductive path, and being configured to generate an induced electrical potential responsive to the first time-varying magnetic field and the second time-varying magnetic field. In some embodiments, the integrated circuit further includes a voltage sensing circuit electrically coupled with the coil structure and configured to measure a voltage level of the induced electrical potential. In some embodiments, the integrated circuit further includes a ferromagnetic structure including an open portion, the first conductive path and the second conductive path extending through the open portion of the ferromagnetic structure. In some embodiments, the first conductive path includes a first conductive line below the ferromagnetic structure, a second conductive line above the ferromagnetic structure, and a first via plug coplanar with the ferromagnetic structure, the first via plug electrically coupling the first conductive line and the second conductive line.
In accordance with another embodiment, an integrated circuit includes a ferromagnetic structure over a substrate, the ferromagnetic structure having a first ferromagnetic portion extending along a first direction. In some embodiments, the integrated circuit further includes a first conductive path over the substrate, the first conductive path being adjacent to the first ferromagnetic portion of the ferromagnetic structure and extends along a second direction different from the first direction. In some embodiments, the first conductive path includes a first conductive line in a first interconnect layer under the ferromagnetic structure, a second conductive line in a second interconnect layer over the ferromagnetic structure, and a first via plug coplanar with the ferromagnetic structure, the first via plug electrically coupling the first conductive line in the first interconnect layer and the second conductive line in the second interconnect layer. In some embodiments, the integrated circuit further includes a second conductive path over the substrate, the second conductive path being adjacent to the first conductive path and the first ferromagnetic portion, and extending along the second direction. In some embodiments, the integrated circuit further includes a coil structure over the substrate, the coil structure being wrapped around the ferromagnetic structure.
In accordance with another embodiment, a method of operating an integrated circuit includes generating a time-varying magnetic field based on a time-varying current on a first conductive path of the integrated circuit or a second conductive path, the first conductive path and the second conductive path extending through an open portion of a ferromagnetic structure. In some embodiments, the first conductive path includes a first conductive line in a first interconnect layer under the ferromagnetic structure, a second conductive line in a second interconnect layer over the ferromagnetic structure, and a via plug coplanar with the ferromagnetic structure, the via plug electrically connecting the first conductive line in the first interconnect layer and the second conductive line in the second interconnect layer. In some embodiments, the method further includes generating an induced electrical potential by a coil structure of the integrated circuit based on the time-varying magnetic field, the coil structure being magnetically coupled with the first conductive path and the second conductive path through the time-varying magnetic field.
The foregoing outlines features of several embodiments so that those skilled in the art may better understand the aspects of the present disclosure. Those skilled in the art should appreciate that they may readily use the present disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the present disclosure, and that they may make various changes, substitutions, and alterations herein without departing from the spirit and scope of the present disclosure.
This application is a continuation of U.S. application Ser. No. 15/053,619, filed Feb. 25, 2016, now U.S. Pat. No. 10,878,997, issued Dec. 29, 2020, which claims the benefit of U.S. Provisional Application No. 62/133,228, filed Mar. 13, 2015, which are herein incorporated by reference in their entireties.
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| Child | 17125020 | US |
