ELECTRONICS PACKAGE HAVING A MULTI-THICKNESS CONDUCTOR LAYER AND METHOD OF MANUFACTURING THEREOF
An electronics package includes an insulating substrate and electrical components coupled to a first surface of the insulating substrate. A multi-thickness conductor layer is formed on a second surface of the insulating substrate opposite the first surface. The multi-thickness conductor layer extends through vias in the insulating substrate to connect with contact pads of the electrical components. The multi-thickness conductor layer has a first thickness in a region proximate the first electrical component and a second thickness in a region proximate the second electrical component, the first thickness greater than the second thickness. The electronics package also includes a first redistribution layer having a conductor layer formed atop a portion of the multi-thickness conductor layer having the second thickness. A top surface of the conductor layer is co-planar with or substantially co-planar with a top surface of a portion of the multi-thickness conductor layer having the first thickness.
Embodiments of the invention relate generally to semiconductor device packages or electronics packages and, more particularly, to an electronics package that includes a conductor layer with locally varied thicknesses. This multi-thickness conductor layer combines high current carrying capabilities and a high density interconnection structure into a common horizontal plane, which facilitates the integration of different types of electronics devices in a miniaturized package topology.
As semiconductor device packages have become increasingly smaller and yield better operating performance, packaging technology has correspondingly evolved from leaded packaging, to laminated-based ball grid array (BGA) packaging, to chip scale packaging (CSP), then flipchip packages, and now buried die/embedded chip build-up packaging. Advancements in semiconductor chip packaging technology are driven by ever-increasing needs for achieving better performance, greater miniaturization, and higher reliability.
A challenge to existing manufacturing techniques is the miniaturization of electronics packages that incorporate different types of individually packaged semiconductor dies that have different current carrying and routing density requirements, such as a mixture digital semiconductor devices and power semiconductor devices. The general structure of a prior art electronics package 10 incorporating a number of individually packaged components 12, 14, 16, 18 is shown in
In the illustrated example, individually packaged devices 14, 16 each include a respective semiconductor device or die 28, 30 having contact pads 32 formed on an active surface thereof. Die 28, 30 are provided on a mounting platform 34, 36 and encased within an insulating material 38, 40. Wirebonds 42, 44 form direct metal connections between active surfaces of respective die 28, 30 and a metalized input/output (I/O) provided on or coupled to the lower surface of die 28, 30. In the case of discrete component 14, wirebonds 42 form an electrical connection between contact pads 32 of die 28 to I/O pads 46 provided on a bottom surface of discrete component 14. Wirebond 42 electrically couples contact pads 32 to I/O leads 48. Where die 30 is a diode, for example, wirebond 42 may connect to the anode on a first surface of the die 30 and a second surface of the die 30 may be soldered to the leadframe. I/O pads 46 and I/O leads 48 are coupled to electrical contacts 24 of PCB 20 by way of metalized connections 26. The overall thickness 50 of such prior art IC packages may be in the range of 500 μm-2000 μm or larger.
Alternatively, electrical connections between components may be realized using a combination of thick and thin conductor layers that are electrically connected to the appropriate semiconductor dies or power devices using through hole or via technology. However, inclusion of multiple routing layers adds considerable thickness to the overall electronics package, a factor that in combination with the complex conductor structure, limits product level miniaturization, design flexibility, and cost efficiency. Additionally, both of the aforementioned techniques include multiple routing layers, which results in a long and complex conductor structure between electrical components and weakens the electrical performance of the overall package, which is increasingly unfavorable in high performance packaging (e.g., high frequency, RF, intelligent power, and other advanced electronics packaging).
Accordingly, it would be desirable to provide a new electronics packaging technology that permits electrical components of different types to be integrated into a highly miniaturized electronics package with locally enhanced electrical and thermal conductivity for certain electronics components and increased routing density in regions proximate other electronics components. It would further be desirable for such a packaging technology to permit a shorter conductor length between electrical components and improve signal fidelity.
BRIEF DESCRIPTION OF THE INVENTIONIn accordance with one aspect of the invention, an electronics package includes an insulating substrate, a first electrical component coupled to a first surface of the insulating substrate, and a second electrical component coupled to a first surface of the insulating substrate. A multi-thickness conductor layer is formed on a second surface of the insulating substrate opposite the first surface. The multi-thickness conductor layer extends through vias in the insulating substrate to connect with at least one contact pad of the first electrical component and at least one contact pad of the second electrical component. The multi-thickness conductor layer has a first thickness in a region proximate the first electrical component and a second thickness in a region proximate the second electrical component, the first thickness greater than the second thickness. The electronics package also includes a first redistribution layer having a conductor layer formed atop a portion of the multi-thickness conductor layer having the second thickness. A top surface of the conductor layer is co-planar with or substantially co-planar with a top surface of a portion of the multi-thickness conductor layer having the first thickness.
In accordance with another aspect of the invention, a method of manufacturing an electronics package includes providing an insulating substrate, coupling a first electrical component and a second electrical component to a first surface of the insulating substrate, and forming a multi-thickness conductor layer on a second surface of the insulating substrate, opposite the first surface. The multi-thickness conductor layer extends through a plurality of vias in the insulating substrate to electrically couple with contact pads of the first and second electrical components and has a first thickness in a region proximate the first electrical component and a second thickness in a region proximate the second electrical component, the first thickness greater than the second thickness. The method also includes forming a first redistribution layer atop a portion of the multi-thickness conductor layer having the second thickness, the first redistribution layer including a conductor layer having a top surface co-planar with or substantially co-planar with a top surface of a portion of the multi-thickness conductor layer having the first thickness.
In accordance with yet another aspect of the invention, an electronics package includes an insulating substrate, a first electrical component having an active surface with at least one contact pad positioned thereon coupled to a first surface of the insulating substrate, and a second electrical component having an active surface with at least one contact pad positioned thereon coupled to the first surface of the insulating substrate. A first conductor layer is disposed on a second surface of the insulating substrate and extending through metallized vias formed through a thickness of the insulating substrate. The first conductor layer has a region with a first thickness electrically coupled to at least one contact pad on the active surface of the first electrical component. The first conductor layer also has a region with a second thickness electrically coupled to at least one contact pad on the active surface of the second electrical component. The electronics package also includes a second conductor layer disposed atop a portion of the first conductor layer having the second thickness. The second conductor layer has a top surface that is co-planar with or substantially co-planar with a top surface of a portion of the first conductor layer having the first thickness.
These and other advantages and features will be more readily understood from the following detailed description of preferred embodiments of the invention that is provided in connection with the accompanying drawings.
The drawings illustrate embodiments presently contemplated for carrying out the invention.
In the drawings:
Embodiments of the present invention provide for an electronics package that includes multiple semiconductor devices, dies, or chips coupled to a patterned conductor layer with locally varied thicknesses. This multi-thickness conductor layer is contained within a common horizontal plane of the electronics package and includes regions having different routing density and current carrying capabilities, the benefits of which may be leveraged for I/O connections to a single electrical component or to multiple electrical components within the electronics package. As described in more detail below, in the case of a multi-chip module portions of the multi-thickness conductor layer include a low density routing pattern that provides the requisite current carrying capabilities for one type of electrical component, such as a power semiconductor die, while other, thinner portions of the conductor layer have a high density routing pattern that enables routing capability below 100/100 μm L/S for another type of electrical component, such as a digital semiconductor die.
As used herein, the phrase “power semiconductor device” refers to a semiconductor component, device, die or chip designed to carry a large amount of current and/or support a large voltage. Power semiconductor devices are typically used as electrically controllable switches or rectifiers in power electronic circuits, such as switched mode power supplies, for example. Non-limiting examples of power semiconductor devices include insulated gate bipolar transistors (IGBTs), metal oxide semiconductor field effect transistors (MOSFETs), bipolar junction transistors (BJTs), integrated gate-commutated thyristors (IGCTs), gate turn-off (GTO) thyristors, Silicon Controlled Rectifiers (SCRs), diodes or other devices or combinations of devices including materials such as Silicon (Si), Silicon Carbide (SiC), Gallium Nitride (GaN), and Gallium Arsenide (GaAs). In use, power semiconductor devices are typically mounted to an external circuit by way of a packaging structure, with the packaging structure providing an electrical connection to the external circuit and also providing a way to remove the heat generated by the devices and protect the devices from the external environment. Typical power semiconductor devices include two (2) to four (4) input/output (I/O) interconnections to electrically connect both sides of a respective power semiconductor device to an external circuit.
As used herein, the phrase “digital semiconductor device” refers to a semiconductor component, device, die, or chip provided in the form of a digital logic device, such as a microprocessor, microcontroller, memory device, video processor, or an Application Specific Integrated Circuit (ASIC), as non limiting examples. As is understood in the art, digital semiconductor devices have reduced current carrying requirements and require increased routing density as compared to power semiconductor devices due to the differences in interconnection pitch and number of I/Os between the device types. A digital semiconductor device may include anywhere between ten and thousands of I/Os depending on the device configuration.
While the electrical components embedded in the electronics package are referenced below in the embodiments of
Referring now to
A number of semiconductor devices or die 108, 110 are coupled to a bottom surface 112 of insulating substrate 106. In the illustrated embodiment described herein, die 108 is a power semiconductor device and die 110 is a digital semiconductor device. However, electronics package 100 may include any combination of electrical components requiring different current carrying and routing density capabilities in alternative embodiments. In one embodiment, a layer of insulating material 114 is used to affix semiconductor devices 108, 110 to insulating substrate 106. As used herein the phrase “insulating material” refers to an electrically insulating material that adheres to surrounding components of the electronics package such as a polymeric material (e.g., epoxy, liquid crystal polymer, ceramic or metal filled polymers) or other organic material as non-limiting examples. In some embodiments, insulating material 114 may be provided in either an uncured or partial cured (i.e., B-stage) form. Alternatively, insulating material 114 may be applied to semiconductor devices 108 and/or 110 prior to placement on insulating substrate 106. In alternative embodiments, semiconductor devices 108, 110 may be affixed to insulating substrate 106 by way of an adhesive property of the insulating substrate 106 itself. In such an embodiment, insulating material 114 is omitted and insulating substrate 106 is provided in the form of a single dielectric layer having adhesive properties. Non-limiting examples of such an adhesive dielectric layer include a spin-on dielectric such as polymide or polybenzoxzaole (PBO).
As shown, semiconductor devices 108, 110 are positioned such that a top surface or an active surface 116, 118 comprising electrical contact pads 120, 122 or connection pads is positioned into insulating material 114. Contact pads 120, 122 provide conductive routes (I/O connections) to internal contacts within each semiconductor device 108, 110. Contact pads 120, 122 may have a composition that includes a variety of electrically conductive materials such as aluminum, copper, gold, silver, nickel, or combinations thereof as non-limiting examples. Depending upon the functionality and complexity of the semiconductor devices 108, 110, the number of contact pads 120, 122 on the respective semiconductor device 108, 110 are increased and the pad pitch (i.e., the center-to-center distance between adjacent contact pads) is reduced. In the case where power semiconductor device 108 is an IGBT, for example, contact pads 120, 122 are coupled to corresponding emitter and/or gate or anode regions of the semiconductor device 108. In the illustrated embodiment power semiconductor device 108 optionally also includes at least one lower contact pad 124 (shown in phantom) or collector pad that is disposed on its backside or lower surface 126. While not shown in the illustrated embodiment, it is contemplated that other types of electrical components, including discrete or passive devices, such as, for example, a resistor, a capacitor, or an inductor, may be affixed to insulating substrate 106 by way of insulating material 114.
Multi-thickness conductor layer 102 is an electrically conductive material that creates a series of electrical connections to the contact pads 120, 122 of power semiconductor device 108 and digital semiconductor device 110. In one embodiment, multi-thickness conductor layer 102 is formed of copper. However, other electrically conducting materials or a combination of metal and a filling agent may be used in other embodiments. As described in more detail below, multi-thickness conductor layer 102 may also include an interstitial seed metal layer (not shown). Multi-thickness conductor layer 102 extends through a series of vias 128, 130 formed through a thickness 132 of insulating substrate 106 to connect to contact pads 120, 122 on respective power and digital semiconductor devices 108, 110.
Multi-thickness conductor layer 102 is fabricated having regions with locally varied planar thicknesses. As shown in
Referring now to
Referring first to
Semiconductor devices 108, 110 are coupled to insulating substrate 106 by positioning the active surfaces 116, 118 of the respective devices 108, 110 on the insulating material 114 using conventional pick and place equipment and methods, as shown in
Referring now to
Upon securing semiconductor devices 108, 110 onto the insulating substrate 106 and following the formation of vias 128, 130, the vias 128, 130 are cleaned (such as through a reactive ion etching (RIE) desoot process or laser process) and subsequently metalized to form multi-thickness conductor layer 102. The manufacture of multi-thickness conductor layer 102 begins by forming a first conductor layer 142 on top surface 104 of insulating substrate 106 in a next step of the fabrication process, as shown in
First conductor layer 142 extends through vias 128, 130 and electrically couples with contact pads 120, 122 of semiconductor devices 108, 110. First conductor layer 142 is formed having a thickness 138 that enables a high density routing capability for digital semiconductor die 110. As used herein, the phrase “high density routing capability” refers to a routing capability below 100/100 μm L/S (line/space). In an exemplary embodiment, thickness 138 is in the range of approximately 4 μm-30 μm. However, one skilled in the art will recognize that the thickness 138 of first conductor layer 142 may be varied to correspond to the interconnection pitch of a particular digital semiconductor die 110.
As shown in
After the first layer photoresist mask 144 is removed, a second layer photoresist mask 146 (
Referring now to
As shown in
In some embodiments, power semiconductor device 108 and digital semiconductor device 110 are overcoated with a layer of electrically insulating material 156 to provide rigidity and ease of handling and to prevent arcing between semiconductor devices and other metal components in high voltage applications. Such a configuration is applicable in embodiments where the power semiconductor device 108 is a lateral device that does not include a connection to the backside of the device 108.
An electrical connection to lower contact pad 124 of power semiconductor device 108 may be made using a conductive substrate 158, as shown in
An alternative technique for manufacturing the electronics package 100 of
Referring now to
Next, a high density L/S pattern is defined by removing select portions of the first photoresist mask 162 and the second photoresist mask 164 aligned with the first conductor layer 142. The exposed portions of first conductor layer 142 are removed using an etching technique resulting in the formation of the high density L/S pattern, as shown in
Referring first to
A third conductor layer 184 is formed on the top surface 182 of insulating substrate 176 and extends through vias 180 to electrically connect with first conductor layer 142. Third conductor layer 184 functions as a routing layer for digital semiconductor die 110. In the illustrated embodiment, the thickness 186 of third conductor layer 184 is selected such that a combined thickness of first conductor layer 142, third conductor layer 184, and the dielectric therebetween is equal to or substantially equal to the thickness 134 of second conductor layer 148, such that the top surfaces of second and third conductor layers 148, 184 are co-planar or substantially co-planar. Similar to first conductor layer 142, third conductor layer 184 is an electrically conductive material such as, for example, copper, and may be formed using a sputtering and plating technique, followed by a lithography process. Together insulating substrate 176, vias 180, and third conductor layer 184 form the redistribution layer 174. It is contemplated that additional redistribution layers may be formed atop redistribution layer 174 as needed to achieve a desired routing pattern to contact pads 122 of digital semiconductor die 110.
Similar to electronics package 166, the electronics packages 168, 170 illustrated in
In the embodiment illustrated in
The electronics package 172 illustrated in
Beneficially, use of the multi-layer conductor layer enables locating disparate electrical components much closer in proximity to each other than prior art techniques such as that shown in
While not shown in
Referring now to
Similar to electronics package 100 (
As shown in
In one embodiment, the first portion 218 of multi-thickness conductor layer 212 has a width 232 that is less than a width 234 of the second portion 222 of multi-thickness conductor layer 212, as shown in
In the illustrated embodiment, the first portions 218 of adjacent routing paths 236 are arranged parallel or substantially parallel to one another while the second portions 222 thereof extend away from electrical component 214 in a substantially radial pattern. However, it is contemplated that the second portion 222 of multi-thickness conductor layer 212 may be formed having any number of alternative geometries or patterns to take advantage of the increased surface area available on the top surface of insulating substrate 106 away from electrical component 214. By increasing the thickness of the routing paths 236 in the region distant the electrical component 214, the routing path 236 may be formed having a shorter electrical delay than prior art configurations. Thus, the multi-thickness conductor layer 212 beneficially permits miniaturization of the overall electronics package 210 while allowing for lower loss connections, as the impedance of a given connection or trace is dependent on the length and cross-sectional area of the trace.
An exemplary technique for manufacturing the electronics package 210 of
As shown in
Next, a first layer photoresist mask 240 (
Referring now to
Another embodiment of an electronics package 248 incorporating a multi-thickness conductor layer 250 coupled to a single electrical component 252 is shown in
Referring now to
In other applications, the varied thicknesses of routing paths may be used to provide enhanced signal communication to one or more particular contact pads in instances where the intra-pad pitch limits width of the routing path to a particular contact pad. In such cases, the thickness of the routing path to a particular contact pad may be increased to provide enhanced current carrying capabilities to or from that particular pad. In applications where routing paths are made to multiple contact pads of a particular component or device, some or all of those routing paths may be formed having increased thickness regardless of the size or functionality of the corresponding contact pads and/or vias. In one non-limiting embodiment, the routing paths are formed in a manner that maximizes use of the routing paths with increased thickness. Additionally, as shown in
A technique for manufacturing the electronics package 248 of
Next, a first layer photoresist mask 274 (
Routing paths 260, shown in
It is contemplated that alternative techniques than those shown in
Either of electronics package 210 (
Therefore, according to one embodiment of the invention, an electronics package includes an insulating substrate, a first electrical component coupled to a first surface of the insulating substrate, and a second electrical component coupled to a first surface of the insulating substrate. A multi-thickness conductor layer is formed on a second surface of the insulating substrate opposite the first surface. The multi-thickness conductor layer extends through vias in the insulating substrate to connect with at least one contact pad of the first electrical component and at least one contact pad of the second electrical component. The multi-thickness conductor layer has a first thickness in a region proximate the first electrical component and a second thickness in a region proximate the second electrical component, the first thickness greater than the second thickness. The electronics package also includes a first redistribution layer having a conductor layer formed atop a portion of the multi-thickness conductor layer having the second thickness. A top surface of the conductor layer is co-planar with or substantially co-planar with a top surface of a portion of the multi-thickness conductor layer having the first thickness.
According to another embodiment of the invention, a method of manufacturing an electronics package includes providing an insulating substrate, coupling a first electrical component and a second electrical component to a first surface of the insulating substrate, and forming a multi-thickness conductor layer on a second surface of the insulating substrate, opposite the first surface. The multi-thickness conductor layer extends through a plurality of vias in the insulating substrate to electrically couple with contact pads of the first and second electrical components and has a first thickness in a region proximate the first electrical component and a second thickness in a region proximate the second electrical component, the first thickness greater than the second thickness. The method also includes forming a first redistribution layer atop a portion of the multi-thickness conductor layer having the second thickness, the first redistribution layer including a conductor layer having a top surface co-planar with or substantially co-planar with a top surface of a portion of the multi-thickness conductor layer having the first thickness.
According to yet another embodiment of the invention, an electronics package includes an insulating substrate, a first electrical component having an active surface with at least one contact pad positioned thereon coupled to a first surface of the insulating substrate, and a second electrical component having an active surface with at least one contact pad positioned thereon coupled to the first surface of the insulating substrate. A first conductor layer is disposed on a second surface of the insulating substrate and extending through metallized vias formed through a thickness of the insulating substrate. The first conductor layer has a region with a first thickness electrically coupled to at least one contact pad on the active surface of the first electrical component. The first conductor layer also has a region with a second thickness electrically coupled to at least one contact pad on the active surface of the second electrical component. The electronics package also includes a second conductor layer disposed atop a portion of the first conductor layer having the second thickness. The second conductor layer has a top surface that is co-planar with or substantially co-planar with a top surface of a portion of the first conductor layer having the first thickness.
While the invention has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the invention is not limited to such disclosed embodiments. Rather, the invention can be modified to incorporate any number of variations, alterations, substitutions or equivalent arrangements not heretofore described, but which are commensurate with the spirit and scope of the invention. Additionally, while various embodiments of the invention have been described, it is to be understood that aspects of the invention may include only some of the described embodiments. Accordingly, the invention is not to be seen as limited by the foregoing description, but is only limited by the scope of the appended claims.
Claims
1. An electronics package comprising:
- an insulating substrate;
- a first electrical component coupled to a first surface of the insulating substrate;
- a second electrical component coupled to the first surface of the insulating substrate;
- a multi-thickness conductor layer formed on a second surface of the insulating substrate opposite the first surface, the multi-thickness conductor layer extending through vias in the insulating substrate to connect with at least one contact pad of the first electrical component and at least one contact pad of the second electrical component, wherein the multi-thickness conductor layer has a first thickness in a region proximate the first electrical component and a second thickness in a region proximate the second electrical component, the first thickness greater than the second thickness; and
- a first redistribution layer comprising a conductor layer formed atop a portion of the multi-thickness conductor layer having the second thickness, wherein a top surface of the conductor layer of the first redistribution layer is co-planar with or substantially co-planar with a top surface of a portion of the multi-thickness conductor layer having the first thickness.
2. The electronics package of claim 1 further comprising an insulating material provided on the first surface of the insulating substrate; and
- wherein the first electrical component and the second electrical component are coupled to the first surface of the insulating substrate by way of the insulating material.
3. The electronics package of claim 1 wherein the first electrical component comprises a power semiconductor device and the second electrical component comprises a digital semiconductor device.
4. The electronics package of claim 1 wherein a bottom surface of the multi-thickness conductor layer facing the insulating substrate is co-planar or substantially co-planar.
5. The electronics package of claim 1 wherein the region of the multi-thickness conductor layer proximate the first electrical component has a low density routing pattern and the region of the multi-thickness conductor layer proximate the second electrical component has a high density routing pattern.
6. The electronics package of claim 1 wherein the first redistribution layer comprises an insulating substrate disposed atop the portion of the multi-thickness conductor layer having the second thickness; and
- wherein the conductor layer of the first redistribution layer extends through a plurality of vias in the insulating substrate of the first redistribution layer to electrically couple with the portion of the multi-thickness conductor layer having the second thickness.
7. The electronics package of claim 1 further comprising a second redistribution layer formed atop and electrically coupled with the first redistribution layer and the portion of the multi-thickness conductor layer having the first thickness.
8. The electronics package of claim 7 further comprising an electrical component positioned between the insulating substrate and a conductor layer of the second redistribution layer, the electrical component electrically coupled to the conductor layer of the second redistribution layer.
9. The electronics package of claim 1 wherein the conductor layer of the first redistribution layer has a thickness equal to or substantially equal to the second thickness of the multi-thickness conductor layer.
10. The electronics package of claim 1 further comprising an insulating material coupled to the first surface of the insulating substrate and surrounding exposed surfaces of the first electrical component and the second electrical component.
11. The electronics package of claim 1 further comprising a conductive substrate electrically coupled to a contact pad positioned on a backside of the first electrical component.
12. The electronics package of claim 1 further comprising a plurality of input/output (I/O) connections formed on a top surface of the multi-thickness conductor layer and electrically coupled to the first electrical component and the second electrical component.
13. A method of manufacturing an electronics package comprising:
- providing an insulating substrate;
- coupling a first electrical component and a second electrical component to a first surface of the insulating substrate;
- forming a multi-thickness conductor layer on a second surface of the insulating substrate, opposite the first surface, the multi-thickness conductor layer extending through a plurality of vias in the insulating substrate to electrically couple with contact pads of the first and second electrical components, wherein the multi-thickness conductor layer has a first thickness in a region proximate the first electrical component and a second thickness in a region proximate the second electrical component, the first thickness greater than the second thickness; and
- forming a first redistribution layer atop a portion of the multi-thickness conductor layer having the second thickness, the first redistribution layer comprising a conductor layer having a top surface co-planar with or substantially co-planar with a top surface of a portion of the multi-thickness conductor layer having the first thickness.
14. The method of claim 13 wherein forming the multi-thickness conductor layer comprises:
- forming a first conductor layer on the second surface of the insulating substrate, the first conductor layer extending through the plurality of vias to electrically couple with contact pads of the first and second electrical components;
- forming a second conductor layer on a first portion of the first conductor layer proximate the first electrical component;
- patterning a second portion of the first conductor layer proximate the second electrical component to define a high density routing pattern; and
- patterning the second conductor layer and the first portion of the first conductor layer to define a low density routing pattern.
15. The method of claim 13 further comprising forming a second redistribution layer atop the first redistribution layer and atop the portion of the multi-thickness conductor having the first thickness.
16. The method of claim 15 further comprising:
- embedding at least one electronics component into an insulating material of at least one of the first redistribution layer and the second redistribution layer; and
- electrically coupling the at least one electronics component to a conductor layer of the second redistribution layer.
17. The method of claim 15 further comprising electrically coupling the second redistribution layer to the multi-thickness conductor layer.
18. The method of claim 13 further comprising surrounding the first and second electrical components with an insulating material.
19. The method of claim 13 further comprising coupling a conductive substrate to a contact pad located on a backside of the first electrical component.
20. An electronics package comprising:
- an insulating substrate;
- a first electrical component having an active surface with at least one contact pad positioned thereon coupled to a first surface of the insulating substrate;
- a second electrical component having an active surface with at least one contact pad positioned thereon coupled to the first surface of the insulating substrate;
- a first conductor layer disposed on a second surface of the insulating substrate and extending through metallized vias formed through a thickness of the insulating substrate, the first conductor layer having a region with a first thickness electrically coupled to at least one contact pad on the active surface of the first electrical component, and the first conductor layer having a region with a second thickness electrically coupled to at least one contact pad on the active surface of the second electrical component; and
- a second conductor layer disposed atop a portion of the first conductor layer having the second thickness, the second conductor layer having a top surface co-planar with or substantially co-planar with a top surface of a portion of the first conductor layer having the first thickness.
21. The electronics package of claim 20 wherein a bottom surface of the first conductor layer facing the second surface of the insulating substrate is co-planar or substantially co-planar in the region having the first thickness and the region having the second thickness.
22. The electronics package of claim 20 wherein the first electrical component comprises a power semiconductor device and the second electrical component comprises a digital semiconductor device.
23. The electronics package of claim 20 further comprising a third conductor layer formed atop the second conductor layer and the portion of the first conductor layer having the first thickness and electrically coupled thereto.
24. The electronics package of claim 23 further comprising at least one electronics component embedded between the third conductor layer and the insulating substrate.
Type: Application
Filed: Nov 4, 2016
Publication Date: May 10, 2018
Inventors: Risto Ilkka Tuominen (Tokyo), Arun Virupaksha Gowda (Rexford, NY)
Application Number: 15/343,248