Patent Publication Number: US-9848500-B2

Title: Method of manufacturing a package for embedding one or more electronic components

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of U.S. application Ser. No. 13/348,295, filed Jan. 11, 2012, which is based upon and claims the benefit of priority to European patent application 11151208.3 filed on Jan. 18, 2011. The entire contents of the foregoing application is hereby incorporated by reference into the present disclosure. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates to a method of manufacturing a carrier structure of a package for embedding one or more electronic components, in particular microwave integrated circuits and discrete passive components, and to a method of manufacturing a package comprising one or more electronic components. 
     Further, the present invention relates to a carrier structure of a package for embedding one or more electronic components, in particular microwave integrated circuits and discrete passive components, to an electronic component for being embedded in a carrier structure of a package and to a package comprising such a carrier structure and one or more electronic system embedded therein. 
     BACKGROUND OF THE INVENTION 
     WO 2004/070835 A1 discloses a method for producing microsystems comprising microelectronic components that are inserted into cavities created during the layered construction of a base body consisting of a photocurable material, said components being situated adjacent to and/or above one another on several planes and being interconnected either electrically or thermally. Once said microelectronic components have been inserted, the layered construction of the base body continues and a structure is constructed consisting of an electrically or thermally conductive material that projects vertically above the contacts (pads) of the electronic component, said conductive material producing a direct connection to an additional electronic component above the first electronic component or to one or several additional electronic components that is or are located at a lateral distance from said first component by means of a conductor track that runs horizontally from the conductive material projecting vertically above the pad. Such a method is also known as RMPD (Rapid Micro Product development) method. 
     These and other known methods for manufacturing a package for embedding one or more electronic components, in particular microwave integrated circuits and discrete passive components, and methods for manufacturing electronic systems show various problems or disadvantages. 
     The size of MMICs (Monolithically Microwave Integrated Circuits) at mm-wave/THz frequencies is often larger than half the free space wavelength λ 0 . This is certainly true when multiple system functions are integrated on a single MMIC. At THz frequencies chip-to-chip connections become very lossy and single-chip analog front-ends or multi-channel chips will likely be encountered with sizes larger than λ 0 . At chip interconnections guided wave modes get disturbed. In these regions modal coupling to unwanted cavity modes inside the package can be excited. The same modal coupling mechanisms can occur in unshielded filter sections. The package gets prone to such coupling effects when the cavities get larger than λ/2 where λ is the free space wavelength divided by the square root of the dielectric constant of the package material. Largest cavity sizes are possible using air cavities. 
     Dielectric losses of packaging materials increase with frequency. Thus, the full embedding of MMICs in dielectric material is practically not attractive anymore at mm-wave/THz frequencies but is done at lower frequencies. In addition, MMICs also change their behavior due to the change in the propagation constants in such an approach. 
     The most rigorous way to suppress cavity modes inside the package is to reduce the size of the cavities below the critical size of λ/2 where λ is the wavelength in the dielectric material (λ≦λ 0 ). This requires the attachment of a lid on the MMIC. The photolithographically structured features on the front side of the MMIC become very small and little area is available for lid attachment on the chip. Specific processes are necessary to attach and connect a lid onto a MMIC. MMICs are often thin and fragile, and mechanical attachment to the lid is difficult, e.g. using a flip-chip approach. An alternative solution may be using lids that do not touch the MMIC but employ periodic bandgap structures. They are often difficult to design and their ability to suppress cavity modes is band-limited. In addition small manufacturing changes may shift the suppression band. Packaging of wideband systems is challenging. Alternatively, wideband absorbing materials can be introduced but they also absorb energy of information carrying guided modes. 
     Filter structures are required in most of receiving or transmitting mm-wave/THz systems. Their size is large compared to the wavelength and integration of such components into the package may either alter the original filter characteristic or disturb other functional blocks of the system due to modal coupling into spurious package modes. 
     Current low volume package solutions are composed of several different parts that need to be assembled together. Assembly and machining tolerances are critical. Achieving hermetic or near-hermetic sealing requires specialized attachment methods. On the other hand a simple package structure is required with as little manual or semi-automated assembly steps as possible. In addition, batch processing is a fundamental requirement for low-cost production. 
     Many packaging approaches at mm-wave and THz frequencies cannot be decomposed into electromagnetically separated units. Multichip packages are difficult to design and hard to debug due to the complex electromagnetic situation inside the package. This leads to long design cycles. Alternatively each functional block requires a separate package which leads to the problem of interconnecting these packages at mm-wave/THz frequencies. The so called split block technology is commonly in use in these scenarios which may lead to bulky and expensive electronic systems. 
     It shall be noted that herein reference is made to the frequency range of 30-300 GHz as mm-wave frequency range. THz frequencies and THz applications often refer falsely to a spectrum starting from 300 GHz in literature. This commonly accepted definition is adopted hereinafter, although the spectrum should actually be called the Sub-THz frequency range. Thus, references made to THz frequencies hereinafter shall be understood as comprising a frequency range from at least 300 GHz to 3 THz. Hereinafter, reference is also made to microwave frequencies, which shall be understood as the same frequency range of approximately 30 GHz to 3 THz. Microwave integrated circuits may operate up to at least 3 THz. 
     BRIEF SUMMARY OF THE INVENTION 
     It is an object of the present invention to provide a method of manufacturing a carrier structure of a package for embedding one or more electronic components and to a method of manufacturing a package by which the above explained disadvantages are prevented. 
     It is a further object of the present invention to provide a carrier structure of a package for embedding one or more electronic components, an electronic component for being embedded in a carrier structure and to a package by which the above explained disadvantages are prevented. 
     According to an aspect of the present invention there is provided a method of manufacturing a carrier structure of a package for embedding one or more electronic components, in particular microwave integrated circuits and discrete passive components, said method comprising the steps of: 
     forming a back-side metallization layer, 
     forming a polymer profile in layers on top of said backside metallization layer by subsequently forming two or more polymer layers by photo polymerisation, wherein one or more cavities are formed in said polymer profile for placing one or more electronic components therein, said electronic components having a back-side terminal and one or more front-side terminals, 
     forming a front-side metallization layer on top of said polymer profile. 
     According to a further aspect of the present invention there is provided a carrier structure of a package for embedding one or more electronic components, in particular microwave integrated circuits and discrete passive components, comprising: 
     a back-side metallization layer, 
     a polymer profile formed in layers on top of said backside metallization layer by subsequently forming two or more polymer layers by photo polymerisation, said polymer profile comprising one or more cavities for placing one or more electronic components therein, said electronic components having a back-side terminal and one or more front-side terminals, and 
     a front-side metallization layer on top of said polymer profile. 
     According to a further aspect of the present invention there is provided a method of manufacturing a package comprising one or more electronic components, said method comprising the steps of: 
     fixedly embedding one or more electronic components, in particular microwave integrated circuits, in one or more cavities of a carrier structure of a package, in particular of a carrier structure as proposed according to the present invention, said carrier structure having a back-side metallization layer, a profile formed on top of said backside metallization layer, said profile comprising one or more cavities for placing one or more electronic components therein, and a front-side metallization layer on top of said profile, said electronic components having a back-side terminal connecting to said front-side metallization layer of said carrier structure and one or more front-side terminals, 
     forming an intermediate cover layer, in particular of a polymer or a dielectric material, on top of said carrier structure and said embedded one or more electronic components, wherein intermediate connection terminals are provided in said intermediate cover layer for connection to said front-side metallization layer of said carrier structure and/or to one or more front-side terminals of said one or more electronic components, 
     forming a signaling metallization layer in predetermined areas on top of said cover layer, said signaling metallization layer connecting to at least one front-side terminal of said respective electronic component through at least one intermediate connection terminal, 
     forming a top cover layer, in particular of a polymer or a dielectric material, on top of said intermediate cover layer and said signaling metallization layer, respectively, wherein top connection terminals are provided in said top cover layer for connection to predetermined intermediate connection terminals, and 
     forming a top metallization layer in predetermined areas on top of said top cover layer connecting through said top connection terminals and predetermined intermediate connection terminals to one or more front-side terminals of one or more predetermined electronic components and/or to said front-side metallization layer of said carrier structure. 
     According to a further aspect of the present invention there is provided an electronic component, in particular microwave integrated circuit or discrete passive component, in particular for being embedded in a carrier structure of a package as proposed according to the present invention, comprising: 
     a central component body comprising one or more functional elements, 
     a back-side terminal provided on a back-side of said central component body for connection to a front-side metallization layer of said carrier structure, and 
     one or more front-side terminals on a front-side of said central component body 
     Finally, according to a further aspect of the present invention there is provided a package comprising: 
     a carrier structure, said carrier structure having a back-side metallization layer, a profile formed on top of said backside metallization layer, said profile comprising one or more cavities for placing one or more electronic components therein, and a front-side metallization layer on top of said profile, 
     one or more electronic components, in particular microwave integrated circuits and discrete passive components, embedded in one or more cavities formed in said carrier structure, 
     an intermediate cover layer, in particular of a polymer or a dielectric material, formed on top of said carrier structure and said embedded one or more electronic components, wherein intermediate connection terminals are provided in said intermediate cover layer for connection to said front-side metallization layer of said carrier structure and/or to one or more front-side terminals of said one or more electronic components, 
     a signaling metallization layer formed in predetermined areas on top of said cover layer, said signaling metallization layer connecting to at least one front-side terminal of said respective electronic component through at least one intermediate connection terminal, 
     a top cover layer, in particular of a polymer or a dielectric material, formed on top of said intermediate cover layer and said signaling metallization layer, respectively, wherein top connection terminals are provided in said top cover layer for connection to predetermined intermediate connection terminals, and 
     a top metallization layer formed in predetermined areas on top of said top cover layer connecting through said top connection terminals and predetermined intermediate connection terminals to one or more front-side terminals of one or more predetermined electronic components and/or to said front-side metallization layer of said carrier structure. 
     Preferred embodiments of the invention are defined in the dependent claims. It shall be understood that the claimed devices and methods generally have similar and/or identical preferred embodiments as described herein and as defined in the dependent claims. 
     The present invention is based on the idea to provide a carrier structure of a package and a monolithic multichip package that fully shields different functions of the electronic system, e.g. of a mm-wave/THz system. The package is preferably poured into place by polymerizing photo sensitive monomers. It gradually grows around and above the electronic components, e.g. MMICs, making connection to the electronic components, but recessing the high frequency areas of the electronic component. 
     The proposed approach leads to functional blocks that are electromagnetically completely shielded. These units can be combined and cascaded according to system needs. The danger is minimized that unwanted resonant modes inside the package are excited which cause system failures hard to debug. The functional blocks once characterized properly can be used in system simulations to investigate arbitrary system architectures. Rapid translation of system level designs into a real package will become possible and may accelerate the development of such electronic systems. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       These and other aspects of the present invention will be apparent from and explained in more detail below with reference to the embodiments described hereinafter. In the following drawings 
         FIG. 1  shows a diagram showing the performance of a low noise amplifier in air and covered by polymer, 
         FIG. 2  shows an embodiment of a known electronic system, 
         FIG. 3  shows an embodiment of a carrier structure of a package according to the present invention, 
         FIG. 4  shows an embodiment of manufacturing a package as shown in  FIG. 5  according to the present invention, 
         FIG. 5  shows an embodiment of a package according to the present invention, 
         FIG. 6  shows a flow chart illustrating a method of manufacturing the carrier structure of the package according to the present invention, 
         FIG. 7  shows a flow chart illustrating a method of manufacturing the package according to the present invention, 
         FIG. 8  shows a perspective view of a stripline interconnection according to the present invention, 
         FIG. 9  shows a cross section of a stripline interconnection according to the present invention, 
         FIGS. 10A-10D  show different views of a cavity filter according to the present invention, 
         FIGS. 11A and 11B  show different views of a waveguide transition according to the present invention, 
         FIGS. 12A-12D  show package layouts and chip layouts according to various embodiments of the present invention, 
         FIGS. 13A and 13B  show an embodiment of cascading different functional blocks in an electronic system according to the present invention, 
         FIG. 14  shows an embodiment of the packaging of a receiver according to the present invention, 
         FIG. 15  shows another embodiment of a carrier structure of a package according to the present invention with a first embodiment of means for heat transfer, and 
         FIG. 16  shows another embodiment of a carrier structure of a package according to the present invention with a second embodiment of means for heat transfer. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The present invention makes use of a method of manufacturing by which packages for embedding one or more electronic components, in particular microwave integrated circuits and discrete passive components (e.g. capacitors or resistors), are more or less cast from a single piece of material. The final package is in that sense a kind of monolithic package. The package material is preferably a light sensitive monomer that is steadily poured into place in thin layers and hardened by photo polymerization using light at UV or other wavelengths. 
     Such methods have become available in recent years for manufacturing of microparts and are used for integrating chips at lower frequencies, i.e. frequencies much below the microwave spectrum. Micrometer precision in vertical and lateral dimensions is possible. Common materials belong to the group of acrylics. However, these materials often exhibit high dielectric losses which are not very attractive for multichip packages at mm-wave/THz frequencies. Such a manufacturing process is, for instance, known as RMPD (Rapid Micro Product development) process. 
     Full embedding of mm-wave/THz MMICs (Monolithically Microwave Integrated Circuits) into acrylic materials has been investigated by electromagnetic simulations. The results, in particular the low noise amplifier performance in the frequency range from 110 to 170 GHz in air and, alternatively, covered by polymer material, are depicted in  FIG. 1 . The curve  10   a ,  10   b  depicts the gain in dB of the amplifier, wherein the curve  10   a  is the gain for a chip in air and the curve  10   b  is the gain for the same chip covered by polymer. The curves  11   a ,  11   b  and  12   a ,  12   b  depict the amount of reflections at the input and output, also for the chip in air (curves  11   a ,  12   a ) and the chip covered by polymer (curves  11   b ,  12   b ). The gain drops significantly when the chip is covered by the polymer material. Such an alteration of chip performance is prohibited for most of the systems at mm-wave/THz frequencies. 
     The conventional packaging approach for MEMS and low frequency circuits using the RMPD process fully embeds a silicon chip into polymer as depicted in  FIG. 2  showing an electronic system  20  in which the chip  22  is fully embedded into a package material  24  (polymer). On top of the chip  22  there is chip metallization layer  26 , which partly connects to a metal package interconnection layer  28 . At the used frequencies the chip package is much smaller than a wavelength, e.g. at 5 GHz the wavelength λ in the package material (dielectric constant ∈ R =2.7) is 36 mm. Packages smaller than 18 mm are not prone to parasitic cavity modes. In comparison the material wavelength λ at 140 GHz is about 1.3 mm. The width of the investigated MMIC in  FIG. 1  is 1 mm which is greater than λ/2. 
     As shown in  FIG. 2  at transitions  30  there exist unwanted excitation paths  32  for unwanted spurious package modes  34  in such electronic systems  20 . Such spurious package modes may lead to resonances and losses which shall generally avoided. 
     The method of manufacturing a carrier structure of a package and of a package according to the present invention shall be illustrated by use of  FIGS. 3 to 7 .  FIG. 3  shows an embodiment of a carrier structure of a package manufactured according to the manufacturing method of the present invention.  FIG. 4  shows an intermediate step for manufacturing a package according to a manufacturing method of the present invention.  FIG. 5  shows an embodiment of package manufactured according to this manufacturing method.  FIG. 6  shows a flow chart illustrating the steps of a method for manufacturing a carrier structure according to the present invention as shown in  FIG. 3 .  FIG. 7  shows a flow chart illustrating the steps of a method for manufacturing package according to the present invention in accordance with  FIGS. 4 and 5 . 
     First, an embodiment of the method  100  for manufacturing a carrier structure  40  of a package  70  for embedding one or more electronic components  50 ,  60 , in particular microwave integrated circuits and discrete passive components, shall be explained with reference to  FIGS. 3 and 6 . 
     In a first step S 10  of the method  100  a back-side metallization layer  41  is formed. In a second step S 12  a polymer profile  42 , in particular a staircase profile, is formed in layers on top of said backside metallization layer  41  by subsequently forming two or more polymer layers. Said polymer layers (which can not be separately identified in  FIG. 3 ) are poured gradually into place by photo polymerization of the polymer, in particular a basic monomer in liquid form. The solid profile  42  is built up in small layers which allows steep sidewalls with little taper. Otherwise the subsequent metallization step S 14  would not reliably coat on cavities  43 ,  44  and particularly on deep trenches  45  formed in said polymer profile  42 . Subsequently, in step S 14  a front-side metallization layer  46  is formed on top of said polymer profile  42  resulting in the carrier structure  40  of package  70 . 
     The cavities  43 ,  44  are provided in the carrier structure  40  for placing one or more electronic components  50 ,  60  therein. Preferably, each electronic component is placed in a separate cavity. The electronic components  50 ,  60  for placement in such a carrier structure  40  generally have a back-side terminal  51 ,  61  for connection to said front-side metallization layer  46  of the carrier structure  40  and one or more front-side terminals  52 ,  62 , to which other connections can be made when the complete package is manufactured as will be explained below. In the embodiment shown in  FIGS. 2 to 5  the electronic component  50  is a microwave integrated circuit, in particular a MMIC, and the electronic component  60  is a discrete passive component, e.g. a discrete capacitor. 
     Next, an embodiment of the method  200  for manufacturing the package  70  shown in  FIG. 5  shall be explained with reference to  FIGS. 4, 5 and 7 . 
     In a first step S 20  of the method  200  (depicted in  FIG. 7 ) the electronic components  50 ,  60  are fixedly placed in the respective cavities  43 ,  44  of the carrier structure  40 . In particular, as shown in  FIG. 3 , the microwave integrated circuit  50  is placed in the cavity  43  and the discrete capacitor  60  is placed in the cavity  44 . The carrier structure  40  of the package  70  is preferably manufactured by a method as explained above, but may also be manufactured by other methods. For instance, the profile  42  may be formed of silicon rather than polymer. 
     In a second step S 22 , as shown in  FIG. 4 , an intermediate cover layer  71 , in particular of a polymer or a dielectric material, is formed on top of said carrier structure  40 , in particular on top of said front-side metallization layer  46 , and on top of said embedded electronic components, i.e. covering at least part of said front-side terminals  52 ,  62 . As shown in  FIG. 4  the material of the cover layer  71  is also filled into some or all trenches  45  and into the gaps  47  that have remained between the electronic components  50 ,  60  and the side walls of the cavities  43 ,  44 . Recesses are reserved in areas  73  and  74  for forming metalized connections to the front-side terminals  52 ,  62  of said electronic components  50 ,  60 . 
     Further, in this step S 22  intermediate connection terminals  73 ,  74  are manufactured in said intermediate cover layer  71  for connection to one or more front-side terminals  52 ,  62  of said electronic components  50 ,  60 . The intermediate connection terminals  73  connect to the front-side terminals  52  of the microwave integrated circuit  50  and the intermediate connection terminals  74  connect to the front-side terminals  62  of the capacitor  60 . The intermediate connection terminals  73  and  74  are first not metalized. These are only recesses in the intermediate cover layer  71 . When forming the signaling layers  76  (in a metallization step) the electrical connections to the terminals front-side terminals  52 ,  62  on said electronic components is achieved. 
     Further, in this embodiment of the method recesses  72  (or openings) are provided in the intermediate cover layer  71 , into which top connection terminals  78  are introduced in a later step, either separately or together with a top metallization layer  81  formed in step S 28 , as will be explained below. These connection terminals (formed at the positions of the recesses  72 ) are provided for connection to the front-side metallization layer  46  of said carrier structure  40 . Thus, in successive metallization steps or the step that forms the signaling layer the top metallization layer connects through the recess  72  the structures underneath, i.e. it is a coating process that coats the sidewalls (where wanted). 
     Preferably, a connection layer  75  is formed on top of the front-side terminal  62  of the capacitor  60  between the intermediate connection terminals  74 . 
     In the next step S 24  a signaling metallization layer  76  is formed in predetermined areas on top of said intermediate cover layer  71 , said signaling metallization layer  76  connecting to at least one front-side terminal  52 ,  62  of the electronic components  50 ,  60  through at least one intermediate connection terminal  73 ,  74 . In case of component  60  the top-side terminal  62  is a lot larger compared to component  50 . The recess that realizes the connection terminal  75  is also larger. The signaling layer  76  coats the recesses and makes a connection to the top side terminals  52 ,  62  of the electronic components  50 ,  60 . 
     In step S 26  a top cover layer  77 , in particular of a polymer or a dielectric material, is formed on top of said intermediate cover layer  71  and said signaling metallization layer  76 , respectively. Preferably, said top cover layer  77  is grown separately on a dummy carrier (not shown). It is only partially polymerized. The top cover layer  77  remains sticky for this reason. This top cover layer  77  is then attached (flipped) to the intermediate cover layer  71  (or vice versa the package is flipped onto layer  77  on the carrier). Then the dummy carrier is removed. Finally the polymerization is completed by further exposure by light. In this way the air cavity  82  is formed. 
     Further, top connection terminals  78 ,  79  are provided in said top cover layer  77 . The top connection terminals  78  are provided for connection to predetermined intermediate connection terminals  72 . The top connection terminals  79  are provided for connection to parts of the signaling metallization layer  76 , in particular the parts of the signaling metallization layer  76  contacting to intermediate connection terminals  73  that are in contact with front-side terminals  52  of the microwave integrated circuit  50 . These top connection terminals  78 ,  79  are preferably manufactured by providing corresponding recesses  80  (as a kind of placeholders) in the top cover layer  77 , into which the top connection terminals  78 ,  79  are introduced separately or together with a top metallization layer  81  formed in step S 28 . In general, all “terminals” are initially not metalized. The metallization step coats the recess and establishes an electrical connection to the layers underneath. 
     Said top metallization layer  80  is formed in predetermined areas on top of said top cover layer  77  connecting through said top connection terminals  78 ,  79  and predetermined intermediate connection terminals  72 ,  73  to one or more front-side terminals  52  of one or more predetermined electronic components, here the microwave integrated circuit  50 , and/or to said front-side metallization layer  46  of said carrier structure  40 . 
     It shall be noted that the intermediate cover layer  71  and the top cover layer  77  are preferably formed from the same material and by use of the same general method as the polymer profile  42 . Further, the thickness of the various layers, in particular of the layers constituting the polymer profile  42 , intermediate cover layer  71  and the top cover layer  77  can be controlled through the polymerization. Generally, the thickness of a single layer is not larger than the height of the smallest “stair” of the staircase polymer profile  42 . Typical thicknesses for a layer are in the range from 10 μm to 100 μm, for instance the cavity  43  is approximately 50 μm. The thickness of the package  40  is, for instance, approximately 300 μm. The intermediate cover layer  71  and the top cover layer  77  are each 20 μm thick for example. 
       FIG. 5  shows the package  70  as a result of the method  200  explained above. 
     For fixing the components  50 ,  60  in the respective cavities  43 ,  44  (in step S  20 ) several methods exist. For example, a partially polymerized thin layer on top of the staircase ground plane, i.e. the front-side metallization layer  46  on the bottom of the cavities, can be grown that has a certain adhesion. In another embodiment, a controlled amount of epoxy can be dispensed inside the cavities  43 ,  44  before component placement. In some embodiments the cavities  43 ,  44  are generally only a few micrometers wider than the actual components  50 ,  60  to be embedded therein, i.e. the gap  47  is generally rather small. This provides the further possibility of fixing the components  50 ,  60  in the cavities  43 ,  44  by pouring and polymerizing one or more next layers on top of the components  43 ,  44 , such as the intermediate cover layer  71  as explained above. 
     During the formation (i.e. the growing and solidifying) of the intermediate cover layer  71  in step S 22  a lift-off metallization step is preferably introduced where the microwave integrated component  50  is protected by a protection layer (not shown), e.g. a photoresist layer. Then, an air cavity  82  (see  FIGS. 4 and 5 ) is formed in this embodiment above the microwave integrated component  50 . Preferably a separate air cavity is formed above each microwave integrated component. 
     The top cover layer  77  and/or said top metallization layer  81  is formed by a transfer process using a sacrificial carrier substrate. In particular the partially polymerized thin lid layer  77  representing said top cover layer  77  is attached in a transfer process with a sacrificial carrier substrate. Polymerization is completed after attachment. Final metallization and photolithographic structuring completes the manufacture. The whole electronic system is in the end one solid unit since the different layers attach to each other just by polymerization and without the use of special gluing layers of other materials. Hermeticity is also guaranteed with this manufacturing approach which thus is an ideal solution for many sensing applications. 
     Microwave integrated components, like component  50 , in particular MMICs, in accordance with the present invention and used in electronic systems according to the present invention have, as indicated in  FIG. 3 , a central component body  53  comprising one or more functional elements, a back-side terminal  51  provided on a back-side of said central component body  53  and one or more front-side terminals  52  on a front-side of said central component body  53 . Further, metalized via holes  54  to the back-side terminal  51  are provided that prevent the excitation of modes inside the central component body  53  (also called MMIC substrate). 
     The staircase ground plane, i.e. the front-side metallization layer  46 , draws through parts of the carrier structure  40  and connects to the back-side metallization layer  41  at the edges  47  of the component areas of the carrier structure, i.e. around the one or more areas in which the cavities  43 ,  44  are located. Both metallization layers  41  and  46  are structured with the same or different masks. They form a faraday shield  48  (i.e. some kind of closed chamber  48 ) between the edges  47  where they contact each other, inside which no package modes can exist. 
     In an embodiment some defined compartments  45 ′ (also called polymer-free grooves or trenches) are opened and used to form the sidewalls of certain elements like cavity resonator filters, cavity backed antennas, orthogonal waveguide transitions or the like. For instance, as shown in  FIG. 5 , a fully shielded filter  83  is formed by a cavity resonator fed by metallized groove  84 , which is formed by a groove  45 , which is covered (in particular in step S 24 ) by the signaling metallization layer  76 , which contacts to the back-side metallization layer  41  at the bottom of the groove  45 . When, in step S 26  the top cover layer  77  is formed, the material of the top cover layer  77  (e.g. polymer) is also filled into the groove  45 . The shielding of the filter  83  is obtained by forming contacting the front-side metallization layer  46  to the back-side metallization layer  41  in the neighboring grooves  45 . 
     In other words, the filter  83  is composed of cavity resonators. The sidewalls are formed by the metalized grooves  45 . Not all grooves  45  are metalized. The metallization layer  46  closes the cavity resonator on the top. Through a small aperture in the metallization layer  46  the cavity is excited/fed by metalized groove  84 . The metalized groove  84  may connect to the bottom metallization  41  (as depicted in  FIG. 5 ) but may also stop above the bottom metallization. The metalized groove  84  is metalized and connected to the signaling metallization layer  76 . The feed areas around the feed aperture are shielded by through connections  78  and the lid layer  81 . 
     The signaling metallization layer  76  and the top metallization layer  81  together with the front-side metallization layer  46  form a stripline interconnection  85  between different components  50 ,  60  of the package  70 . The signaling metallization layer  76  can represent a stripline interconnection layer and the top metallization layer  81  can represent a lid layer. Both the stripline interconnection layer  76  (here representing the center conductor) and the lid layer  81  may be connected to the back-side metallization layer  41  or to the top metallization layer  46 . A cross section of an implementation of a stripline interconnection  85  (see  FIG. 8 ) is shown in  FIG. 9 . It can be seen that these interconnections  85  are fully shielded. Metallization layer  46  connects to metallization layer  81  surrounding the signal conductor  76 . Chip-to-chip interconnections can be kept shorter than 200 μm and higher dielectric material losses per wavelength can be tolerated up to THz frequencies. The cross section of the stripline interconnection  85  has a very small aperture which gives also an excellent isolation of parasitic evanescent modes that could tunnel through from functional block to functional block. 
     A preferred embodiment of a cavity filter  83  formed by tucking down the front-side metallization layer  46  to the back-side metallization layer  41  is shown in  FIGS. 10A-10D .  FIG. 10A  shows a perspective view of the cavity filter  83 . Particularly a shielded cavity feed  83   a  and a shielded stripline feed  83   b  are shown.  FIG. 10B  shows a cross section of the cavity filter  83  along A-A′. The cavity feed  83   a  with a via through aperture in the staircase ground plane  46 . Further, a shielded stripline interconnection  83   c  is shown.  FIG. 10C  shows a cross section of the cavity filter  83  along B-B′. At position  83   d  the tucking down of the staircase ground plane  46  is interrupted to preserve parallel ground planes ( 46  and  81 ) of the stripline.  FIG. 10D  shows a cross section of the cavity filter  83  along C-C′. A metalized via  83   e  is shown here protruding into the cavity  45 , which may also connect to the back-side metallization layer  41 . 
     A preferred embodiment of a rectangular waveguide interface  86  formed by tucking down the front-side metallization layer  46  to the back-side metallization layer  41  is shown in  FIGS. 11A and 11B .  FIG. 11A  shows a perspective view of the rectangular waveguide interface  86 . Particularly, a stripline feed  86   a  and a polymer support  86   b  to preserve parallel ground planes for the stripline feed  86   a  are shown.  FIG. 11B  shows a cross section of the rectangular waveguide interface  86  along A-A′. 
     Both  FIGS. 10A-10D, 11A, and 11B  show the rigorous shielding concept provided according to preferred embodiments of the present invention. In the same way as the transition to the rectangular waveguide is implemented it is possible to implement a cavity backed planar antenna, for example a patch antenna. 
     The mode conversion from the stripline mode to the cavity mode of the filter or the rectangular waveguide mode occurs while suppressing any radiation into the rest of the package. The metalized sidewalls of both implementations shown in  FIGS. 10A-10D, 11A, and 11B  are tucked down to the backside metal but they are interrupted where polymer supports the ground plane of the stripline, i.e. to support the continuation of the ground plane of the stripline in the vicinity to the center/signal conductor. Otherwise the even stripline mode would be disturbed and reflected. The support is chosen as small as possible to prevent leakage out of the cavity. 
     In another embodiment DC and RF areas (or components) of microwave integrated circuits are strictly separated.  FIG. 12A  shows a top view on a first embodiment of a proposed package layout and  FIG. 12B  shows a top view on a second embodiment of a proposed package layout, as maybe used for embedding a low noise amplifier operating at 140 GHz. The resulting layers for the air cavity  82  and the intermediate connection terminals  73  are also shown in both layouts. 
     The introduction of via holes to connect the lid, i.e. the top metallization layer  81 , down to the MMIC requires supporting polymer material. In the first design example as shown in  FIG. 12A  there are only a few places on the inside of the MMIC where discrete square vias can be placed considering the design rules of the used manufacturing process. The discrete vias are means to suppress cavity modes in the large cavity. Since there are only a few places available the suppression is incomplete in many instances. In other words, suppression of cavity modes may be band-limited (due to the size of the cavity area having a width w of a size in the area of half the wavelength) and incomplete in many instances. The required supporting polymer material may get close to RF transmission lines and detune the MMIC&#39;s performance. 
     The preferably proposed layout shown in  FIG. 12B  allows the minimization of the cavity size (to a width much smaller than half the wavelength) by separating DC and RF components electromagnetically. In particular, the DC and RF components are located in different areas/compartments and shielded by the lid layer ( 76 ,  81 ) tucked down to the MMIC through connections  78 ,  79 . For this purpose shielding connection terminals  87   a ,  87   b  are provided between the areas  88  (realized in this embodiment using layer  76  and  81 ) in which the DC components are placed and the areas  89  in which the RF components are placed as shown in  FIG. 12D  depicting a cross section through an exemplary chip layout shown in  FIG. 12C . In comparison, the conventional chip layout accommodates DC and RF functions in the same air cavity of the package without shielding. Not only becomes the air cavity width close to half the wavelength in air but also parasitic modes could couple into DC networks. 
     One of the features to be highlighted is the consequent introduction of a continuous landing pattern  90   a ,  90   b  for the package metallization layers shown in  FIG. 12C . The areas  91  in the DC sections  88  are ground capacitors that cannot be used as landing areas. The ground parts of the lid  81  are tucked down to the landing patterns  90   a ,  90   b  of the MMIC through the shielding connection terminals  87   a ,  87   b . The continuous landing pattern  90   a ,  90   b  allows almost perfect shielding of functional blocks from each other on a multifunction chip but spares the RF carrying transmission lines from being covered with polymer material. 
     Concerning the modeling of the isolated functional blocks which are completely shielded units an embodiment is proposed that considers mismatch.  FIG. 13A  shows a block diagram of two cascaded amplifier building blocks connected to transmission lines (of the stripline type as proposed according to this invention) at the input and output. Each block in the corresponding system simulation shown in  FIG. 13B  is represented by a package layout component. 
     Once each functional block is characterized it can be used to investigate different system architectures and automatically transfer the systems into a package design which is ready for manufacturing. An example of a packaged receiver, as an exemplary embodiment of an electronic system  70 ′ containing amplifier MMICs  50   a - 50   c , integrated passive components  60   a - 60   d  the filter component  83  as described above, an integrated antenna  91  and I/O pads  92  (and possibly further components) is shown in  FIG. 14  to demonstrate the simple construction of a system out of basic well defined components that is enabled by use of the present invention. Here the receiver can be considered as a system-in-package although no baseband signal processing function is included in the package, but is rather an electronic sub-system. 
     Typical polymer materials used for packaging have a relatively low thermal conductivity. Hence, in a further embodiment of a carrier structure  40 ′ illustrated in  FIG. 15  as a cross section one or more a polymer-free heat conducting grooves  95  are formed below parts of one or more cavities  43  so that the front-side metallization layer  46  contacts the back-side metallization layer  41  when formed on top of the polymer profile  42 . Subsequently, before the microwave integrated component  50  is placed into the cavity  43 , a heat conductive material  96 , in particular epoxy or solder, is filled into said heat conducting grooves  95 . This improves the heat transfer to the backside of the carrier structure  40 ′ enabling higher power applications. 
     In an alternative embodiment of a carrier structure  40 ″ illustrated in  FIG. 16  as a cross section a heat conductive cavity  97  is formed below the central part of one or more cavities  43 . Said heat conductive cavity  97  has a smaller width than the adjacent cavity  43 . Further, the heat conductive cavity is formed such that the front-side metallization layer  46  contacts the back-side metallization layer  41  when formed on top of the polymer profile  42 . Subsequently, before the microwave integrated component is placed into the cavity  43 , a heat conductive element  98 , in particular a metallic block such as a solid metal base plate, is placed into said heat conductive cavity  97 , said heat conductive element having a height such that the bottom surface of the microwave integrated component  50  once embedded into said cavity  43  contacts to the front-side metallization layer  46   a  formed on top of the polymer profile  42  on the bottom  43   a  of the cavity  43  around said heat conductive cavity  97  and to the top surface  98   a  of said heat conductive element  98 . 
     It shall be noted that the heat conductive means shown in the embodiments of  FIGS. 15 and 16  can be provided only beneath selected electric components or beneath all electric components. Preferably, those means are provided for electric components producing much heat during operation. 
     By use of the present invention and the various embodiments the problems and disadvantages of the known methods and systems are overcome. 
     The leveling problem of face-up packaging techniques is solved particularly by manufacturing the package monolithically by a process of polymerization of monomers. The package can be developed in height to any practical relevant thickness (typically occurring in practice) and devices (particularly MMICs and passive chip components) of different thicknesses can be embedded in the package in a face-up mounting technique having their front-side contact area at the same height level. Conventional face-up packaging processes are typically limited in this respect. For instance, in an embodiment the package is grown up to 50 mm (e.g. limited by the current manufacturing machines) which is for most of the practical cases enough, e.g. in combination with microfluidic elements or stacking multiple packages on top of each other. In other implementations the package should be as thin as possible. Generally, the packages are not much thicker as the electronic components embedded (in the order of 300 to 400 μm). 
     The cavity mode problem is solved rigorously in several ways, and thus the package becomes suitable for integrating mm-wave/THz systems. In particular, a staircase ground-plane tucked to the backside metallization of the package is introduced. A faraday shield is realized on which the devices are mounted. Different compartments of this faraday shield can be realized. Some compartments can be opened to realize cavity filters, cavity backed antennas or back shorts for transitions to rectangular waveguides. The feeding of these compartments is fully shielded. 
     Further, the manufacturing process is used to realize a lid touching the MMIC but creating a small cavity above the RF parts of the MMIC. If the material would touch the MMIC RF parts they would not function to their optimum and losses would increase. The lid is thus preferably designed to shield different functions of the MMIC from each other. This is achieved by the introduction of continuous landing patterns on the MMIC, rigorously dividing the MMIC into functional blocks, for example separating RF and DC parts, and continuously connecting the ground layers of the lid to the MMIC. 
     Still further, the stripline transmission line type is preferably used to interconnect all RF components. This completes the full shielding concept. In this way a modular library of fully characterized functional blocks is developed that drastically speeds up the development cycles of novel mm-wave/THz systems. 
     Finally, thermal problems are solved by preferably using a thermal management of the face-up packaging approach which is improved by the introduction of fully filled thermal backside vias. 
     Multiple of the proposed packages can be combined to a full electronic system (for example a transmit system part and a receive system part). In general, one of these packages is a vital part of an electronic system working at mm-wave and THz frequencies that capsule all important microwave functions. The remaining parts are signal processing parts at lower GHz frequencies, e.g. at 0-10 GHz. Also external antenna lens parts or antenna reflector parts are left which would enhance the antenna in the package. The antenna in the package may e.g. illuminate a lens or a reflector. For instance multiple packages  70  can be stacked on top of each other and the process steps  100 ,  200  can be repeated on and on. In particular, after a first package is manufactured as explained above, the next package (with the same or different cavities and/or electronic components embedded therein) can be manufactured by the same method on top of the first package. This will particularly be used for manufacturing phased array systems. 
     The proposed package that capsules the mm-wave/THz frequency functions of the system may sometimes also be called a system-in-a-package (SiP) even though strictly speaking digital signal processing functions are part of another package (e.g. a conventional package used in microprocessors etc.). However, bare microprocessor chips could be included in the proposed package as well. 
     According to the present invention the package is grown together with the pattern of thermal vias/interconnections (monolithic aspect). The formation of the vias is not limited to circular via shapes. Further, the pattern can be optimized (honeycomb, circular, pillar type etc) to compromise thermal, mechanical and assembly requirements (amount of epoxy/solder consumed by the vias for example). Still further, it takes generally the same time independent of the thermal interconnection pattern to the backside. Preferably, the vias are closed at the backside, which prevents that the epoxy or solder will run underneath the backside of the package. 
     The top side and bottom side ground of the carrier structure can be connected not only at the edge of the package or by discrete circular vias. Rather a continuous connection (tucking down the topside ground plane to the bottom side ground plane) nearby the MMICs or groups of MMICs is suggested. It is further suggested using this approach to form closed compartments in the substrate to achieve cavity resonators (filled with dielectric material). In that sense a new use of front side—back side connection paths” is proposed. 
     The function of the upper dielectric layer is extended according to the present invention. Preferably, it is not just “perforated” over the chip terminals (which are usually located at the edge of the MMIC) to allow bridging the metal layers on top of said dielectric layer to make connection to the terminals of the chip. Instead, these layers are preferably extended close to the RF sections of the MMICs to form fully shielded compartments or functional blocks or to shield DC and RF parts of MMICs from each other. Functions on a large chip (larger than half the wavelength in the dielectric material) can be separated in that way at THz frequencies to avoid excitation of unwanted resonant modes. Since the dielectric layer is grown arbitrary shaped connections to the MIMIC can be made. Further, the present invention is not bound to form discrete vias in form of circular shape but rather prefers continuous vias for connecting package ground to MMIC ground. 
     The package is also relevant for the implementation of phased array systems of different architectures than explained above (e.g. tray or tile array architectures) where multiple receiver and transmitter channels are integrated in one package. In such scenarios often very tight spacing between the channels is required with minimal cross talk. The proposed approach is ideal to meet such requirements. Further, the package is also relevant for integration of systems with microfluidic features, e.g. in mm-wave/THz spectroscopic system. 
     The invention has been illustrated and described in detail in the drawings and foregoing description, but such illustration and description are to be considered illustrative or exemplary and not restrictive. The invention is not limited to the disclosed embodiments. Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure, and the appended claims. 
     In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. A single element or other unit may fulfill the functions of several items recited in the claims. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the claims should not be construed as limiting the scope.