Patent Application
20100052839
The present invention relates generally to semiconductor devices, and more particularly to transformers.
Semiconductor devices are used in a variety of electronic applications, such as personal computers, cell phones, digital cameras, and other electronic equipment, as examples. Semiconductor devices are typically fabricated by sequentially depositing insulating or dielectric layers, conductive layers, and semiconductive layers of material over a semiconductor substrate, and patterning the various layers using lithography to form circuit components and elements thereon.
A transformer is an electrical device that transfers energy. A transformer has an input side including a primary winding and an output side including a secondary winding. Electrical energy applied to the primary winding is converted to a magnetic field which induces a current in the secondary winding. The current in the secondary winding carries energy to a load connected to the secondary winding. The energy applied to the primary winding is usually in the form of a changing voltage, which creates a constantly changing current in the primary winding, causing a changing magnetic field. The changing magnetic field produces a current in the secondary winding.
Transformers are typically used to convert energy or to isolate an energy source. Transformers can convert energy on the primary winding to a different voltage level on the secondary winding by using different turn counts on the primary and secondary windings. The voltage ratio of the transformer is the same as the turn ratio of the primary and secondary windings. Transformers may be used to isolate the energy source from the destination energy source, for safety reasons or to allow a voltage offset between the source and the load. Furthermore, transformers may also be used to transform impedance.
Transformers are generally divided into two main types: power transformers and signal transformers. Power transformers are used to convert voltages and provide operating power for electrical devices. Signal transformers are used to transfer information from one form or location to another form or location.
In some semiconductor device applications, transformers are required, such as in radio frequency (RF) circuits, analog circuits, power amplifiers, or other types of semiconductor devices. Using external transformers with semiconductor devices can be expensive and can increase the bill-of-materials (BOM) for an application. Furthermore, external transformers are large and require a large amount of space.
Forming transformers in conductive material layers of semiconductor devices results in transformers having a low quality factor (Q). The thin metal layers of semiconductor devices limit the type, size, and operating characteristics of the transformer that can be formed. An attempt to increase the thickness of conductive material layers in order to build an on-chip transformer would result in increased costs for the semiconductor devices.
Thus, what are needed in the art are improved transformer designs for semiconductor device applications.
Technical advantages are generally achieved by embodiments of the present invention, which include novel designs for transformers and methods of manufacture thereof.
In accordance with one embodiment, a transformer includes a semiconductor workpiece, and a packaging system disposed over the semiconductor workpiece. The packaging system includes a redistribution layer. At least a portion of at least one winding of the transformer is disposed in the redistribution layer of the packaging system.
The foregoing has outlined rather broadly the features and technical advantages of embodiments of the present invention in order that the detailed description of the invention that follows may be better understood. Additional features and advantages of embodiments of the invention will be described hereinafter, which form the subject of the claims of the invention. It should be appreciated by those skilled in the art that the conception and specific embodiments disclosed may be readily utilized as a basis for modifying or designing other structures or processes for carrying out the same purposes of the present invention. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the invention as set forth in the appended claims.
For a more complete understanding of the present invention, and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
Corresponding numerals and symbols in the different figures generally refer to corresponding parts unless otherwise indicated. The figures are drawn to clearly illustrate the relevant aspects of the preferred embodiments and are not necessarily drawn to scale.
The making and using of the presently preferred embodiments are discussed in detail below. It should be appreciated, however, that the present invention provides many applicable inventive concepts that can be embodied in a wide variety of specific contexts. The specific embodiments discussed are merely illustrative of specific ways to make and use the invention, and do not limit the scope of the invention.
Embodiments of the present invention involve vertically stacking primary and secondary windings of a transformer in a semiconductor workpiece and/or in the packaging layers of the semiconductor workpiece. On-chip metallization layers, e.g., the upper conductive material layers of the semiconductor workpiece, are used to form the secondary windings, and a redistribution layer of a packaging system is used to form the primary windings, in some embodiments. Transformers with windings having one or more turns may be formed, and the on-chip metal levels may be used for the crossings and bridges of the winding formed in the redistribution layer. If a second redistribution layer is available in the packaging system, transformers may furthermore be formed only in the packaging system, without requiring the use of silicon in the semiconductor workpiece below the transformer.
The present invention will be described with respect to preferred embodiments in a specific context, namely implemented in semiconductor device applications that require transformers. The invention may also be applied, however, to other applications where transformers are used.
With reference now to
The packaging system shown in
The redistribution layer 104 of the WLB package includes one or more insulating material layers 106. Conductive lines 110 are formed in the redistribution layer 104. In an embodiment, the conductive lines 110 may be formed of a metal (for example, a pure metal or a metal alloy). Alternatively, the conductive lines 110 may comprise other conductive materials. The conductive lines 110 are bonded or coupled to contact pads 112 of the semiconductor workpiece 102. The conductive lines 110 comprise conductive lines in the insulating material layer(s) 106 that couple the plurality of solder ball contacts 108 to contact pads 112 of the semiconductor workpiece 102.
The semiconductor workpiece 102 may be attached to the redistribution layer 104 by an adhesive 114. The contact pads 112 may be soldered to the conductive lines 110 of the redistribution layer 104, which may comprise bond pads on the top surface thereof to couple to the contact pads 112 of the semiconductor workpiece 102. The contact pads 112 may alternatively be attached to the conductive lines 110 using a conductive adhesive, for example. An encapsulating material 116 may be disposed over the entire package, over the redistribution layer 104 and the semiconductor workpiece 102.
In accordance with embodiments of the present invention, the packaged semiconductor workpiece 100 includes a transformer 120 having at least a portion of at least one winding formed or disposed in the redistribution layer 104 of the packaging system. At least a portion of a first winding 122 of the transformer 120 is disposed in the redistribution layer 104 of the packaging system in the embodiment shown in
In some embodiments, at least a portion of a second winding 124 of the transformer 120 is disposed in at least one conductive material layer of the semiconductor workpiece 102. The second winding 124 is disposed proximate the first winding 122, as shown in
The entire first winding 122 may be formed in the redistribution layer 104, or only portions of the first winding 122 may be formed in the redistribution layer 104. If the first winding 122 comprises more than one turn, cross-overs of the first winding 122 may be formed in a conductive material layer of the semiconductor workpiece 102, for example. The entire second winding 124 may be formed in the redistribution layer 104 or in the semiconductor workpiece 102. Alternatively, only portions of the second winding 124 may be formed in the redistribution layer 104, and cross-overs of the second winding 124 may be formed in a conductive material layer of the semiconductor workpiece 102. Alternatively, the second winding 124 may be formed in one or more conductive material layers of the semiconductor workpiece 102, e.g., the second winding 124 may be formed in several conductive material layers, comprising a vertical spiraling loop connected by vias between the conductive material layers in the semiconductor workpiece 102.
The first winding 122 may comprise the primary winding of the transformer 120 in some applications, and the second winding 124 may comprise the secondary winding. Alternatively, in other applications, the first winding 122 may comprise the secondary winding of the transformer 120, and the second winding 124 may comprise the primary winding.
Several examples of embodiments of the invention will next be described.
In the embodiment shown in
The second winding 124 may comprise substantially the same width as the first winding 122, as shown, or alternatively, the second winding 124 may comprise a different width, e.g., greater than or less than the width of the first winding 122, not shown. The second winding 124 may comprise a substantially mirror image of the first winding 122 in some embodiments, as shown.
Conductive lines 126 may be coupled to ends of the second winding 124, as shown. The conductive lines 126 may be connected to a voltage supply terminal, a voltage return terminal, or a terminal for a signal elsewhere in the conductive material layer of the semiconductor workpiece 102 or in the packaged semiconductor workpiece 100, for example.
In the embodiment shown in
For example,
The semiconductor workpiece 102 includes a substrate 101, shown in
The semiconductor workpiece 102 includes a plurality of conductive material layers Mx, Vx, M(x+1) formed over the substrate 101 proximate a top surface of the semiconductor workpiece 102. Conductive lines (not shown) are formed in other regions of the conductive material layers Mx and M(x+1), and vias (also not shown) are formed in other regions of the conductive material layer Vx. Conductive material layer M(x+1) comprises a top-most conductive material layer of the semiconductor workpiece 102, and conductive material layer Mx comprises a second conductive material layer disposed below the conductive material layer M(x+1). The via layer Vx is disposed between the conductive material layers M(x+1) and Mx and is used to make connections between conductive lines in the two conductive material layers M(x+1) and Mx.
Conductive lines formed in other regions of the conductive material layers may comprise a greater width in a top view in the top-most conductive material layer M(x+1) than in the conductive material layer Mx. The portions 124a of the second winding 124 may also comprise a greater width than portions 124b of the second winding 124; e.g., in the embodiment shown, each turn of the portion 124b of the second winding 124 in conductive material layer Mx comprises two conductive lines that run parallel to one another along their length, curving or bending at the same regions.
Vias 136 may be used to connect the portions 124a and 124b of the second winding 124 in the via layer Vx disposed between the conductive material layers M(x+1) and Mx. The portion 124b of the second winding 124 in conductive material layer Mx may include landing pads 134 that provide a place for the vias 136 to land on to connect to ends 130 of the portions 124a in conductive material layer M(x+1). The landing pads 134 are also used to couple together the parallel conductive line portions 124a in conductive material layer Mx.
Some ends 130 of portions 124a of the second winding 124 in the conductive material layer M(x+1) may be connected together by cross-overs 132 of the adjacent conductive material layer Mx, e.g., using one or more vias 136 disposed between the portions 124a and 124b of the second winding 124. As in the previous embodiment, some ends of the portions 124a and 124b of the second winding 124 in the conductive material layers M(x+1) and Mx may be coupled to conductive lines 126a and 126b, respectively. The conductive lines 126a and 126b may be connected to a voltage supply terminal, a voltage return terminal, or a terminal for a signal elsewhere in the conductive material layer of the semiconductor workpiece 102 or in the packaged semiconductor workpiece 100, for example.
Portions 124b of the second winding 124 are disposed proximate portions 124a of the second winding 124 vertically in the packaged semiconductor workpiece 100. Portions 124a of the second winding 124 are disposed proximate the first winding 122 in the redistribution layer 104 shown in
In the embodiment shown in
The portions 124a and 124b of second winding 124 comprise different widths than the first winding 122, as can be seen in the top views in
The portions 124a and 124b of the second winding 124 may also comprise different thicknesses than the thickness of the first winding 122 in the vertical direction in the cross-sectional view of
In
The first portions 122a and the second portions 122b of the first winding form an inductor of the transformer 120 comprising the first winding 122. The first winding 122 comprises a single winding formed from the first portions 122a in the redistribution layer 104 and the second portions 122b in the conductive material layer M(x+1) in the semiconductor workpiece 102.
Landing pads 134 may be coupled to each end of the second portions 122b of the first winding 122, as shown. A contact layer (not shown) in the semiconductor workpiece 102 may be used to make connections to the first portion 122a of the first winding 122 in the redistribution layer 104. Alternatively, the wiring for regions of the first portion 122a of the first winding 122 within the redistribution layer 104 may be extended to the surface of the redistribution layer 104 and may be bonded to the landing pads 134 using solder or conductive adhesive, for example, connecting the second portion 122b to the first portion 122a of the first winding 122 and completing the turns of the first winding 122, forming a continuous first winding 122.
The conductive material layer M(x+1) also includes a portion 124a or a plurality of portions 124a of the second winding 124 comprising two turns. Landing pads 134a may be included along some regions of the portion 124a of the second winding 124 for connecting the portions 124a of the second winding 124 to portions 124b of the second winding 124 in conductive material layer Mx shown in
Conductive lines 139b may be used to connect the portions 124b of the second winding 124 to landing pads 134b, which may be coupled to landing pads 134a by one or more vias, not shown. Ends 130 of the portions 124b of the second winding 124 may be connected by vias to landing pads 134a along regions of the portions 124a of the second winding 124 in conductive material layer M(x+1), to make cross-overs for the portions 124b of the second winding 124 and complete the turns, forming a continuous second winding 124.
Optionally, cross-overs of the first winding 122 may also be made by third portions 122c of the first winding 122 formed in the conductive material layer Mx. The third portions 122c may be coupled to a landing pad 134′ at each end, and the landing pads 134′ may be coupled to landing pads 134 in conductive material layer M(x+1) using vias (not shown) in a via layer Vx disposed between conductive material layers Mx and M(x+1).
The turns of the winding portions 124a may comprise one conductive line, as shown on the right side in
The first winding 122 may have a low impedance and the second winding 124 may have a high impedance in some embodiments. This is an advantage in some applications where the source impedance is taken into consideration or accommodated for in the design, for example.
The first and second windings 122 and 124 are disposed proximate one another vertically and are separated by insulating material 106 in the redistribution layer 104. Cross-overs, e.g., crossings or bridges, of the second winding 124 may be made in the upper conductive material layer of the semiconductor workpiece 102, not shown. This embodiment is advantageous because less space is required on the semiconductor workpiece 102, so that the semiconductor workpiece 102 may be made smaller, or the area saved in the semiconductor workpiece 102 may be used for other circuitry.
If the first and second windings 122 and 124 both comprise a single turn (e.g., one winding or a single loop), no cross-overs may be required in a conductive material layer of the semiconductor workpiece 102, so that the transformers 120 advantageously require no space at all on the semiconductor workpiece 102.
The embodiment shown in
The first winding 122 may comprise a single wide primary winding that may be connected to a power amplifier in this embodiment, as an example. The second winding 124 may be used to convert the energy from the first winding 124, stepping up an alternating current in the first winding 122, as another example.
Embodiments of the present invention include transformers 120 and methods of manufacture thereof. The windings 122 and 124 and portions of the windings 122 and 124 may be manufactured using lithography and etch processes used in semiconductor device fabrication processes and/or using manufacturing processes for redistribution layers of packaging systems. Embodiments of the present invention also include semiconductor devices, integrated circuits, and semiconductor workpieces 102 including and utilizing the novel transformers 120 described herein. Embodiments also include packaged semiconductor workpieces 100 including the transformers 120 formed in at least a portion of the redistribution layer 104 of the packaging system.
Advantages of embodiments of the invention include providing novel transformer 120 designs that have improved quality or Q factors. The windings 122 and 124 comprise inductors of the transformers 120 that are formed in at least a portion of a redistribution layer 104 of a packaging system for the semiconductor workpieces 102. Transformers 120 with increased capability and turn ratios may be manufactured and included in at least a portion of the packaging systems for semiconductor devices. The transformers 120 may be formed in one or more conductive layers of redistribution layers 104 of packaging systems, saving space on semiconductor workpieces 102. The windings 122 and 124 of the transformers 120 are vertically stacked in one or more conductive material layers of a semiconductor workpiece 102 and/or in one or more conductive layers of a redistribution layer 104.
The first winding 122 may comprise a primary winding having a low impedance and a high quality in some embodiments, whereas the second winding 124 may comprise a secondary winding formed on the semiconductor workpiece 102 that has a higher impedance and may have a lower quality, which may be an advantage in some applications.
Although embodiments of the present invention and their advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims. For example, it will be readily understood by those skilled in the art that many of the features, functions, processes, and materials described herein may be varied while remaining within the scope of the present invention. Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification. As one of ordinary skill in the art will readily appreciate from the disclosure of the present invention, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed, that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized according to the present invention. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps.
