Abstract:
A surface mount light emitting package includes a chip carrier having top and bottom principal surfaces. At least one light emitting chip is attached to the top principal surface of the chip carrier. A lead frame attached to the top principal surface of the chip carrier. When surface mounted to an associated support, the bottom principal surface of the chip carrier is in thermal contact with the associated support without the lead frame intervening therebetween.

Description:
[0001]    This application claims the benefit of U.S. provisional application Ser. No. 60/527,969 filed on Dec. 9, 2003. 
     
     BACKGROUND 
       [0002]    The following relates to the lighting arts. It is especially relates to surface-mounted light emitting diodes for indicator lights, illumination applications, and the like, and will be described with particular reference thereto. However, the following will also find application in other areas that advantageously can employ surface-mountable light emitting devices. 
         [0003]    Surface mounted light emitting packages typically employ a light emitting chip such as a light emitting diode chip, a vertical cavity surface emitting laser, or the like. In some arrangements the chip is bonded to a thermally conductive sub-mount which is in turn bonded to a lead frame. The sub-mount provides various benefits such as improving manufacturability of electrical interconnections, improving thermal contact and conduction, and the like. The lead frame is adapted to be surface mounted by soldering to a printed circuit board or other support. 
         [0004]    Such arrangements have certain disadvantages. The thermal transfer path includes two intervening elements, namely the sub-mount and the lead frame. Moreover, electrical connections to the lead frame typically involve wire bonds, which can be fragile. The mechanical connection between the sub-mount and the lead frame is typically effected in part by an epoxy or other type of encapsulating overmolding material. Such materials can have relatively high coefficients of thermal expansion which can stress wire bonds or mechanical connections. 
         [0005]    The present invention contemplates an improved apparatus and method that overcomes the above-mentioned limitations and others. 
       BRIEF SUMMARY 
       [0006]    According to one aspect, a light emitting package is disclosed. A chip carrier includes top and bottom principal surfaces. At least one light emitting chip is attached to the top principal surface of the chip carrier. A lead frame attached to the top principal surface of the chip carrier. 
         [0007]    According to another aspect, a light emitter is disclosed. A chip carrier has top and bottom principal surfaces. At least one light emitting chip is attached to the top principal surface of the chip carrier. A lead frame electrically contacts electrodes of the at least one light emitting chip. A support including printed circuitry is provided. The lead frame electrically contacts the printed circuitry. The chip carrier is secured to the support without the lead frame intervening therebetween. 
         [0008]    According to yet another aspect, a light emitting package comprises a chip carrier and a light emitting chip attached to the chip carrier. 
         [0009]    According to still yet another aspect, a light emitting package comprises a light emitting chip and a lead frame electrically connected to electrodes of the light emitting chip. 
         [0010]    Numerous advantages and benefits of the present invention will become apparent to those of ordinary skill in the art upon reading and understanding the present specification. 
     
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0011]    The invention may take form in various components and arrangements of components, and in various process operations and arrangements of process operations. The drawings are only for purposes of illustrating preferred embodiments and are not to be construed as limiting the invention. The drawings of the light emitting packages are not to scale. 
           [0012]      FIG. 1  shows a side view of a light emitting package surface mounted to a printed circuit board. 
           [0013]      FIGS. 2A and 2B  show top and side views of another light emitting package. 
           [0014]      FIG. 3  shows a top view of yet another light emitting package. 
           [0015]      FIGS. 4A ,  4 B, and  4 C show, respectively, a top view of a chip carrier with four light emitting chips flip-chip bonded thereto, a top view of a lead frame, and a side view of a light emitting package constructed from the components of  FIGS. 4A and 4B . 
           [0016]      FIGS. 5A ,  5 B, and  5 C show, respectively, a top view of a chip carrier with four light emitting chips bonded thereto with a front-side electrode of each chip wire bonded to the chip carrier, a top view of a lead frame, and a side view of a light emitting package constructed from the components of  FIGS. 5A and 5B . 
       
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
       [0017]    With reference to  FIG. 1 , a surface-mounted light emitting package  10  includes a light emitting chip  12 , such as a light emitting diode, a resonant cavity light emitting diode, a vertical cavity surface emitting laser, or the like, bonded to an electrically insulating chip carrier  14 . In  FIG. 1 , a flip-chip bonding configuration is shown in which front-side electrodes of the light emitting chip  12  are bonded to electrically conductive layers  20 ,  22  disposed on a top principal surface  26  of the chip carrier  14 . An insulating gap  28  which may be an air gap or may be filled with an electrically insulating material such as an epoxy or other dielectric. The electrically conductive layers  20 ,  22  define first and second terminals of opposite electrical polarity. Flip-chip electrode bonds  32 ,  34  can be thermosonic bonds, conductive epoxy bonds, solder bonds, or the like. 
         [0018]    The chip carrier  14  is preferably substantially thermally conductive. At least the top principal surface  26  of the chip carrier  14  is substantially electrically insulating. The chip carrier  14  can be made of an electrically insulating material such as semi-insulating silicon, a ceramic, or a thermally conductive but electrically insulating plastic. Alternatively, the chip carrier  14  can be made of an electrically conductive material with an insulating layer or coating applied at least to the top principal surface  26 . For example, the chip carrier  14  can be made of conductive silicon with a silicon dioxide layer disposed on the top principal surface  26 , or the chip carrier  14  can be made of a metal with an insulator disposed on the top principal surface  26 , or so forth. 
         [0019]    The electrically conductive layers  20 ,  22  extend away from the die attach region where the light emitting chip  12  is flip chip bonded. Lead frame elements  40 ,  42 , which are electrically conductive and electrically isolated from one another, are secured to and electrically contact portions of the electrically conductive layers  20 ,  22  distal from the die attach region. The lead frame  40 ,  42  is attached to the top principal surface  26  of the chip carrier  14 . The lead frame element  40  includes an electrical lead  46  distal from the chip carrier  14  and a bend  48  such that the lead  46  is approximately coplanar with a bottom principal surface  50  of the chip carrier  14 . Similarly, the lead frame element  42  includes an electrical lead  52  distal from the chip carrier  14  and a bend  54  such that the lead  52  is approximately coplanar with the bottom principal surface  50  of the chip carrier  14 . Electrical and physical bonding of the lead frame elements  40 ,  42  to the top principal surface  26  of the chip carrier  14  is suitably achieved by solder bonds  54 ,  56 . The lead frame  40 ,  42  is suitably made of copper or another highly conductive material. 
         [0020]    An overmolding or encapsulant  60  is disposed over the light emitting chip  12  and the top principal surface  26  of the chip carrier  14 , and also encapsulates a portion of the lead frame elements  40 ,  42  proximate to the chip carrier  14 . The leads  46 ,  52  of the lead frame  40 ,  42  as well as the bottom principal surface  50  of the chip carrier  14  extend outside of the encapsulant  60 . Optionally, a wavelength-converting phosphor layer  62  coats the encapsulant  60  and fluorescently or phosphorescently converts light emitted by the light emitting chip  12  to another wavelength or range or plurality of wavelengths. 
         [0021]    The chip carrier  14  and the light emitting chip  12  and lead frame  40 ,  42  bonded to the top principal surface  26  of the chip carrier  14 , together with the optional encapsulant  60  and phosphor layer  62 , collectively define a surface mountable unit that is surface-mounted on a printed circuit board  70 . In the example embodiment of  FIG. 1 , the printed circuit board  70  includes a metal board  72 , such as a copper or aluminum board, with an insulating coating  74  disposed on the metal board  72 . Printed traces are disposed on the insulating coating  74  and define a selected electrical circuit or circuits including electrical terminals, bonding bumps, or bonding pads  80 ,  82 . The lead  46  of the lead frame element  40  is soldered to the printed circuitry electrical terminal  80 , while the lead  52  of the lead frame element  42  is soldered to the printed circuitry electrical terminal  82 . The printed traces also includes a thermal terminal  84  which optionally is not connected with the electrical circuitry. The bottom principal surface  50  of the chip carrier  14  is preferably soldered or otherwise bonded to the thermal terminal  84  to provide a substantially thermally conductive pathway therebetween, so that heat generated in the light emitting chip  12  can conduct through the substantially thermally conductive chip carrier  14  to the thermal terminal  84  and thence to the printed circuit board  70 . Optionally, the bottom principal surface  50  of the chip carrier  14  includes a metal layer for solder attach to the board or other coating to enhance thermal contact and heat transfer. 
         [0022]    In one embodiment, the attachment bonding the leads  46 ,  52  to the terminals  80 ,  82  and the attachment bonding the bottom principal surface  50  of the chip carrier  14  to the thermal terminal  84  are the same. For example, these attachments can all be made by solder bonds in a single bonding process. Alternatively, a different type of attachment is used for bonding the bottom principal surface  50  of the chip carrier  14  to the thermal terminal  84  as compared with the type of attachment used for bonding the leads  46 ,  52  to the terminals  80 ,  82 . In this latter approach, the thermal attachment of the chip carrier  14  and the electrical attachments of the leads  46 ,  52  can be separately optimized for thermal and electrical conductance, respectively. 
         [0023]      FIGS. 2A and 2B  show top and side views of a light emitting package  110 . The package  110  is similar to the package  10  of  FIG. 1 . Elements of the light emitting package  110  that correspond with elements of the package  10  are labeled by reference numbers offset by  100 . The package  110  includes a light emitting chip  112  flip chip bonded to conductive layers  120 ,  122  disposed on a top principal surface  126  of a chip carrier  114 . A gap  128  electrically isolates the conductive layers  120 ,  122 . Lead frame elements  140 ,  142  are soldered or otherwise electrically contacted and mechanically bonded with the conductive layers  120 ,  122  disposed on the top principal surface  126  of the chip carrier  114 . The lead frame elements  140 ,  142  each include a bend  148 ,  154  so that electrical leads  146 ,  152  distal from the chip carrier  114  are approximately coplanar with a bottom principal surface  150  of the chip carrier  114 . 
         [0024]    As in the package  10 , at least the top principal surface  126  of the chip carrier  114  is electrically insulating, while the chip carrier  114  can be either electrically insulating, or electrically conductive with an insulator layer providing the electrically insulating top principal surface  126 . The chip carrier  114  is also preferably substantially thermally conductive. The lead frame  140 ,  142  is electrically conductive, and is suitably made of copper or another metal. The package  110  as illustrated does not include an encapsulant or phosphor; however, these components are optionally added. If an encapsulant is added, the bottom principal surface  150  of the chip carrier  114  and the leads  146 ,  152  of the leads should extend outside of the encapsulant. 
         [0025]    Advantageously, the light emitting package  110  does not include wire bonds. Rather, electrical connection between the lead frame  140 ,  142  and the light emitting chip  112  is through the conductive layers  120 ,  122 . As best seen in  FIG. 2A , the conductive layers  120 ,  122  are large area layers, providing good conductance even if the thicknesses of the conductive layers  120 ,  122  is limited. Moreover, the conductive layers  120 ,  122  can be reflective layers that reflectively increase light extraction. The light emitting package  110  is suitable for surface mounting on a printed circuit board or other substrate. To perform surface mounting, the leads  146 ,  152  are soldered or otherwise electrically bonded to bonding bumps, bonding pads, or other electrical terminals of printed circuitry, while the bottom principal surface  150  of the chip carrier  114  is preferably soldered or otherwise thermally bonded to the printed circuit board or other substrate. 
         [0026]    With reference to  FIG. 3 , a light emitting package  210  is described. The package  210  is similar to the package  10  of  FIG. 1 . Elements of the light emitting package  210  that correspond with elements of the package  10  are labeled by reference numbers offset by  200 . The package  210  includes a light emitting chip  212  bonded to a conductive layer  220  disposed on a top principal surface of a chip carrier  214 . Unlike the package  10 , however, in the package  210  the light emitting chip  212  is not flip-chip bonded. Rather, the light emitting chip  212  is bonded in a non-inverted configuration and includes an electrically conductive backside serving as an electrode that is electrically bonded to the conductive layer  220  using thermosonic bonding, conductive epoxy, solder, or the like. The front-side electrode of the light emitting chip  212  is wire bonded to another conductive layer  222  separated from the conductive layer  220  by a gap  228 . The wire bond  290  reaches across the gap  228  to electrically connect a front-side electrode  292  of the light emitting chip  212  with the conductive layer  222 . 
         [0027]    Lead frame elements  240 ,  242  are soldered or otherwise electrically contacted and mechanically bonded with the conductive layers  220 ,  222  disposed on the top principal surface of the chip carrier  214 . Similarly to the corresponding lead frame elements of the packages  10 ,  110 , the lead frame elements  240 ,  242  each include a bend  248 ,  254  so that electrical leads  246 ,  252  are approximately coplanar with a bottom principal surface of the chip carrier  214 . Similarly to the package  10 , an encapsulant  260  encapsulates the light emitting chip  212 , the wire bond  290 , the top principal surface of the chip carrier  214 , and portions of the lead frame elements  240 ,  242 , while the leads  246 ,  252  and the bottom principal surface of the chip carrier  214  extend outside of the encapsulant  260 . Moreover, the light emitting package  210  includes a phosphor coating  262 . 
         [0028]    While phosphor-coated encapsulants are shown in  FIGS. 1 and 3 , it is to be appreciated that encapsulation without a phosphor can be employed instead, or the phosphor can be dispersed in the encapsulant, or the phosphor can be otherwise arranged to interact with light produced by the light emitting chip. Moreover, it is contemplated to include a phosphor layer without an encapsulant, or to include neither an encapsulant nor phosphor, as shown in  FIG. 2 . 
         [0029]    With reference to  FIGS. 4A ,  4 B, and  4 C, a light emitting package  310  is described. The package  310  is similar to the package  10  of  FIG. 1 . Elements of the light emitting package  310  that correspond with elements of the package  10  are labeled by reference numbers offset by  300 . The package  310  includes four light emitting chips  312 A,  312 B,  312 C,  312 D flip-chip bonded to conductive layers  320 ,  322 ,  324  disposed on a top principal surface of a chip carrier  314 . The conductive layers  320 ,  322 ,  324  are arranged with the layer  324  disposed between the layers  320 ,  322  and acting as a series interconnect terminal. The conductive layers  320 ,  324  are separated by a gap  328 , while the conductive layers  322 ,  324  are separated by a gap  330 . The light emitting chips  312 A,  312 B are flip chip bonded across the gap  328  with electrodes bonding to the conductive layers  320 ,  324 , while the light emitting chips  312 C,  312 D are flip chip bonded across the gap  330  with electrodes bonding to the conductive layers  322 ,  324 . Thus, the light emitting chips  312 A,  312 B are connected electrically in parallel with each other, and similarly the light emitting chips  312 C,  312 D are connected electrically in parallel with each other. The parallel combination of chips  312 A,  312 B is connected electrically in series with the parallel combination of chips  312 C,  312 D via the series interconnect terminal conductive layer  324 . 
         [0030]    Lead frame elements  340 ,  342  are soldered or otherwise electrically contacted and mechanically bonded with the conductive layers  320 ,  322  disposed on the top principal surface of the chip carrier  314 . Similarly to the corresponding lead frame elements of the packages  10 ,  110 , the lead frame elements  340 ,  342  each include a bend  348 ,  354  so that electrical leads  346 ,  352  are approximately coplanar with a bottom principal surface of the chip carrier  314 , so that the light emitting chip package  310  can be surface mounted by soldering or otherwise connecting the leads  346 ,  352  of the lead frame elements  340 ,  342  to a printed circuit board or other support. Preferably, the surface mounting also includes forming a solder bond or other thermal contact between the bottom principal surface of the chip carrier  314  and the printed circuit board or other support. Although no encapsulant or phosphor is included in the light emitting package  310 , it will be appreciated that an encapsulant, phosphor, optical components, or the like are optionally included. 
         [0031]    In another embodiment, the light emitting chips  312 B,  312 D are replaced by zener diodes connected across the gaps  328 ,  330 , respectively. The zener diodes provide electrostatic discharge protection for the light emitting chips  312 A,  312 C. Moreover, it will be appreciated that other electronic components can be similarly added along with interconnecting circuitry defined by conductive areas on the top principal surface of the chip carrier  314 . Such other electronic components can regulate behavior of the light emitting chips, for example by providing input voltage conditioning, current limiting, or the like. 
         [0032]    With reference to  FIGS. 5A ,  5 B, and  5 C, a light emitting package  410  is described. The package  410  is similar to the package  310  of  FIGS. 4A ,  4 B, and  4 C. Elements of the light emitting package  410  that correspond with elements of the package  310  are labeled by reference numbers offset by  100 . The package  410  includes four light emitting chip  412 A,  412 B,  412 C,  412 D electrically connected with conductive layers  420 ,  422 ,  424  disposed on a top principal surface of a chip carrier  414 . The conductive layers  420 ,  422 ,  424  are arranged with the layer  424  disposed between the layers  420 ,  422  and acting as a series interconnect terminal. The conductive layers  420 ,  424  are separated by a gap  428 , while the conductive layers  422 ,  424  are separated by a gap  430 . The light emitting chips  412 A,  412 B are arranged in a non-inverted orientation with an electrically conductive backside of each chip serving as an electrode bonded to the conductive layer  420 . Similarly, the light emitting chips  412 C,  412 D are arranged in a non-inverted orientation with an electrically conductive backside of each chip serving as an electrode bonded to the conductive layer  424 . A front-side electrode of the light emitting chip  412 A is wire bonded across the gap  428  to the conductive layer  424  by a wire bond  490 A. Similarly, a front-side electrode of the light emitting chip  412 B is wire bonded across the gap  428  to the conductive layer  424  by a wire bond  490 B. A front-side electrode of the light emitting chip  412 C is wire bonded across the gap  430  to the conductive layer  422  by a wire bond  490 C. A front-side electrode of the light emitting chip  412 D is wire bonded across the gap  430  to the conductive layer  422  by a wire bond  490 D. Thus, the light emitting chips  412 A,  412 B are connected electrically in parallel with each other, and similarly the light emitting chips  412 C,  412 D are connected electrically in parallel with each other. The parallel combination of chips  412 A,  412 B is connected electrically in series with the parallel combination of chips  412 C,  412 D via the series interconnect terminal conductive layer  424 . 
         [0033]    Lead frame elements  440 ,  442  are soldered or otherwise electrically contacted and bonded with the conductive layers  420 ,  422  disposed on the top principal surface of the chip carrier  414 . Similarly to the corresponding lead frame elements of the packages  10 ,  110 , the lead frame elements  440 ,  442  each include a bend  448 ,  454  so that electrical leads  446 ,  452  are approximately coplanar with a bottom principal surface of the chip carrier  414 , so that the light emitting chip package  410  can be surface mounted by soldering or otherwise connecting the leads  446 ,  452  to a printed circuit board or other support. Preferably, the surface mounting also includes forming a solder bond or other thermal contact between the bottom principal surface of the chip carrier  414  and the printed circuit board or other support. Although no encapsulant or phosphor is included in the light emitting package  410 , it will be appreciated that an encapsulant, phosphor, optical components, or the like are optionally included. 
         [0034]    In  FIGS. 3 and 5  a single wire bond is used to electrically connect a frontside electrode of each chip, with the second electrode of each chip corresponding to the electrically conductive backside of the chip. However, it is also contemplated to employ an insulating backside and two front side contacts that are each wire bonded to one of the conductive films disposed on the front principal surface of the chip carrier. 
         [0035]    The light emitting packages described herein are suitably constructed using electronic packaging processes. One example process is as follows. The process preferably starts with a chip carrier wafer which will be diced to produce a large number of light emitting packages each including a chip carrier diced from the chip carrier wafer. If the chip carrier is electrically conductive, it is preferably coated, oxidized, or otherwise processed to form an electrically insulating layer at least on the top principal surface. Two or more patterned conductive layers are formed on the top principal surface of the chip carrier using metal evaporation, electroplating, or the like in conjunction with lithographic techniques that define the electrically isolating gaps between the conductive layers. These patterned conductive layers are the electrical terminal conductive layers, such as the layers  20 ,  22  of the package of  FIG. 1 . Optionally, the bottom principal surface of the chip carrier is also metallized to allow for solder attach to improve thermal conductivity through the bottom principal surface. The light emitting chips are attached mechanically and electrically to the chip carriers by flip-chip bonding, wire bonding, or the like. The chip carrier wafer is then diced to produce a plurality of chip carriers with attached light emitting chips. 
         [0036]    Each chip carrier produced by the dicing is processed in the example process as follows. The top principal surface of the chip carrier is soldered to the lead frame. Preferably, the two lead frame elements are secured together by tabs or other fasteners during this soldering, and in one embodiment a number of such lead frames are secured together in a linear or two-dimensional array to facilitate automated processing. A transfer molding process is used to form the encapsulant over the light emitting chips, the top principal surface of the chip carrier, and portions of the lead frame. The molding die is designed so that the leads and the bottom principal surface of the chip carrier extend outside the molded encapsulant. The tabs of the lead frames are then cut or trimmed to electrically separate the lead frame elements to produce the final light emitting package that is suitable for surface mounting by soldering or the like. 
         [0037]    The invention has been described with reference to the preferred embodiments. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the invention be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.