RF monoblock filter assembly with lid filter

Abstract

An RF filter assembly comprising a monoblock of dielectric material defining a first RF filter and a lid of dielectric material defining a second RF filter. In one embodiment, the monoblock defines a peripheral wall of dielectric material extending upwardly from a top surface thereof and first and second posts of dielectric material also extending upwardly from the top surface of the monoblock including regions of metallization thereon defining respective conductive input/output pads. The lid is seated against the top of the wall of the monoblock in a relationship spaced from the top surface of the monoblock and defines at least one region of metallization on one of the surfaces thereof defining a filter and a conductive input/output pad in coupling relationship with the input/output pad defined on one of the first and second posts on the monoblock.

Description

TECHNICAL FIELD

This invention relates to dielectric block filters for radio-frequency signals, and, in particular, to monoblock passband filters.

BACKGROUND OF THE INVENTION

Ceramic block filters offer several advantages over lumped component filters. The blocks are relatively easy to manufacture, rugged, and relatively compact. In the basic ceramic block filter design, the resonators are formed by typically cylindrical passages, called through-holes, extending through the block from the long narrow side to the opposite long narrow side. The block is substantially plated with a conductive material (i.e. metallized) on all but one of its six (outer) sides and on the inside walls formed by the resonator through-holes.

One of the two opposing sides containing through-hole openings is not fully metallized, but instead bears a metallization pattern designed to couple input and output signals through the series of resonators. This patterned side is conventionally labeled the top of the block. In some designs, the pattern may extend to sides of the block, where input/output electrodes are formed.

The reactive coupling between adjacent resonators is dictated, at least to some extent, by the physical dimensions of each resonator, by the orientation of each resonator with respect to the other resonators, and by aspects of the top surface metallization pattern. Interactions of the electromagnetic fields within and around the block are complex and difficult to predict.

These filters may also be equipped with an external metallic shield attached to and positioned across the open-circuited end of the block in order to cancel parasitic coupling between non-adjacent resonators and to achieve acceptable stopbands.

Although such RF signal filters have received widespread commercial acceptance since the 1980s, efforts at improvement on this basic design continued.

In the interest of allowing wireless communication providers to provide additional service, governments worldwide have allocated new higher RF frequencies for commercial use. To better exploit these newly allocated frequencies, standard setting organizations have adopted bandwidth specifications with compressed transmit and receive bands as well as individual channels. These trends are pushing the limits of filter technology to provide sufficient frequency selectivity and band isolation.

Coupled with the higher frequencies and crowded channels are the consumer market trends towards ever smaller wireless communication devices and longer battery life. Combined, these trends place difficult constraints on the design of wireless components such as filters. Filter designers may not simply add more space-taking resonators or allow greater insertion loss in order to provide improved signal rejection.

A specific challenge in RF filter design is providing sufficient attenuation (or suppression) of signals that are outside the target passband at frequencies which are integer multiples of the frequencies within the passband. The label applied to such integer-multiple frequencies of the passband is a “harmonic.” Providing sufficient signal attenuation at harmonic frequencies has been a persistent challenge.

SUMMARY OF THE INVENTION

The present invention is directed to a composite RF filter assembly in which a monoblock of dielectric material defines a first RF filter and a lid or plate also of dielectric material is mounted over the top of the monoblock and defines a second RF filter.

In one embodiment, the monoblock includes a filter comprising one or more through-holes, a plurality of surfaces including a top surface, one or more walls of dielectric material which extend upwardly from the top surface, and a region of conductive material/metallization on the top surface which extends onto one or more of the walls and defines at least a first input/output pad on one of the walls of the block.

The lid or plate includes first and second opposed surfaces and, in one embodiment, a wide area of conductive material/metallization on the first surface of the plate which defines at least a first input/output pad on the first surface of the plate and a pattern of conductive material/metallization on the second surface of the plate which is coupled at one end to the first input/output pad on the first surface of the plate and at another end to the wide area of conductive material/metallization on the first surface of the plate.

The plate is seated on one or more of the walls of the block in a spaced relationship from the top surface of the block. The first input/output pad on the one of the walls of the block is coupled to the first input/output pad defined on the first surface of the plate and the conductive material/metallization on the one or more of the walls of the block is coupled to the wide area of conductive material/metallization on the first surface of the plate.

In one embodiment, one or more of the walls of dielectric material extending upwardly from the top surface of the block define first and second posts which are covered with conductive material to define first and second input/output pads and at least the first post is in contact with the input/output pad on the first surface of the plate.

In one embodiment, a first strip of conductive material/metallization extends over the top surface and one of the side surfaces of the plate into coupling relationship with the first input/output pad on the first surface of the plate and a second strip of conductive material/metallization extends over the top surface and another of the side surfaces of the plate into coupling relationship with the wide area of conductive material/metallization on the first surface of the plate.

Further, in one embodiment, the plate includes front and back side surfaces and the first strip of conductive material/metallization extends over the front side surface of the plate and the second strip of conductive material/metallization extends over the back side surface of the plate.

In another embodiment, the plate includes end side surfaces and the second strip of conductive material/metallization extends over one of the end side surfaces.

There are other advantages and features of this invention, which will be more readily apparent from the following detailed description of the embodiments of the invention, the drawings, and the appended claims.

BRIEF DESCRIPTION OF THE FIGURES

In the accompanying drawings that form part of the specification, and in which like numerals are employed to designate like parts throughout the same:

FIG. 1 is an enlarged front side perspective view of a monoblock filter with a low pass lid filter according to the present invention;

FIG. 2 is an enlarged front side perspective view of the monoblock filter of FIG. 1 without the lid filter;

FIG. 3 is an enlarged back side perspective view of the monoblock filter of FIG. 1 without the lid filter;

FIG. 4 is an enlarged front side perspective view of the lid filter shown in FIG. 1;

FIG. 5 is an enlarged back side perspective view of the lid filter shown in FIG. 4;

FIG. 6 is an enlarged bottom side perspective view of the lid filter shown in FIG. 4;

FIG. 7 is a graph of signal strength (or loss) versus frequency for the monoblock filter with lid shown in FIG. 1;

FIG. 8 is an enlarged front side perspective view of another embodiment of the lid filter of the present invention;

FIG. 9 is an enlarged bottom side perspective view of the lid filter shown in FIG. 8; and

FIG. 10 is another enlarged bottom side perspective view of the lid filter shown in FIG. 8.

DETAILED DESCRIPTION OF THE EMBODIMENTS

While this invention is susceptible to embodiment in many different forms, this specification and the accompanying drawings disclose a composite RF filter assembly generally designated 800 in FIG. 1 which comprises a monoblock filter 10 as shown in FIGS. 1-3 (i.e., the first filter of the filter assembly 800) and a lid 820 or 920 as shown in FIGS. 1, 4, and 8 (i.e., the second filter of the filter assembly 800) seated and coupled to the top of the filter 10.

Filter 10 is currently the subject of co-pending U.S. patent application Ser. No. 12/316,233 filed on Dec. 9, 2008 and thus the disclosure and contents thereof are expressly incorporated herein by reference.

Filter 10 as shown in FIGS. 1-3 comprises a generally elongate, parallelepiped or box-shaped rigid block or core comprised of a ceramic dielectric material 12 having a desired dielectric constant. In one embodiment, the dielectric material can be a barium or neodymium ceramic with a dielectric constant of about 37 or above. Core 12 (FIGS. 2 and 3) defines an outer surface with six generally rectangular sides: a top side or top surface 14; a bottom side or bottom surface 16 that is parallel to and diametrically opposed from top surface 14; a first side or side surface 18; a second side or side surface 20 that is parallel to and diametrically opposed from side surface 18; a third side or end surface 22; and a fourth side or end surface 24 that is parallel to and diametrically opposed from end surface 22.

Core 12 additionally defines four generally planar walls 110, 120, 130 and 140 of ceramic dielectric material unitary with the ceramic dielectric material of core 12 that extend upwardly and outwardly away from the respective outer peripheral edges of the top surface 14 thereof. Walls 110, 120, 130, 140 and top surface 14 together define a cavity 150 in the top of the filter 10. Walls 110, 120, 130, 140 further together define a peripheral top rim 200 at the top of the walls.

Longitudinal walls 110 and 120 are parallel and diametrically opposed to each other. Transverse walls 130 and 140 are parallel and diametrically opposed to each other.

Wall 110 has an outer surface 111 and an inner surface 112. Outer surface 111 is co-extensive and co-planar with side surface 20 while inner surface 112 slopes or angles outwardly and downwardly away from the rim 200 into top surface 14 to define a surface which is sloped at approximately a 45 degree angle relative to both the top surface 14 and the wall 110. Other slope angles may be used. Walls 120, 130 and 140 all define generally vertical outer walls generally co-planar with the respective core side surfaces and generally vertical inner walls.

Wall 110 additionally defines a plurality of generally parallel and spaced-apart slots 160, 162, 164 and 166 that extend through wall 110 in an orientation generally normal to top surface 14.

An end wall portion 110A is defined between the wall 130 and slot 160. A wall portion or post 110B of ceramic dielectric material unitary with the ceramic dielectric material of core 12 is defined between spaced-apart slots 160 and 162 and extends upwardly and outwardly away from the outer peripheral edge of the top surface 14 of filter 10. Wall portion 110C is defined between slots 162 and 164. A wall portion or post 110D of ceramic dielectric material unitary with the ceramic dielectric material of core 12 is defined between slots 164 and 166 and extends upwardly and outwardly away from the outer peripheral edge of the top surface 14 of filter 10. Post 110D is diametrically opposed to post 110B and is defined in an end portion of wall 110 adjacent the wall 140. An end wall portion 110E is defined between the wall 140 and slot 166.

Inner surface 112 is further separated into several portions including inner angled or sloped surface portions 112A, 112B, 112C, 112D and 112E (FIG. 3). Inner surface portion 112A is located on wall portion 110A. Inner surface portion 112B is located on wall portion or post 110B. Inner surface portion 112C is located on wall portion 110C. Inner surface portion 112D is located on wall portion or post 110D. Inner surface portion 112E is located on wall portion 110E.

Wall portions 110A, 110B, 110C, 110D, and 110E further define generally triangularly-shaped side walls. Specifically, wall portion 110A defines a side wall 114A adjacent to slot 160. Post 110B defines a side wall 114B adjacent to slot 160 and an opposed side wall 114C adjacent to slot 162. Wall portion 110C defines a side wall 114D adjacent to slot 162 and an opposed side wall 114E adjacent to slot 164. Post 110D defines a side wall 114F adjacent to slot 164 and a side wall 114G adjacent to slot 166. Wall portion 110E defines a side wall 114H adjacent to slot 166.

Wall 120 has an outer surface 121 and an inner surface 122. Outer surface 121 is co-extensive and co-planar with side 18 and inner surface 122 is perpendicular to top surface 14.

Wall 130 has an outer surface 131 and an inner surface 132. Outer surface 131 is co-extensive and co-planar with side 22 and inner surface 132 is perpendicular to top surface 14.

Wall 140 has an outer surface 141 and an inner surface 142. Outer surface 141 is co-extensive and co-planar with side 24 and inner surface 142 is perpendicular to top surface 14.

Top surface 14 can have several portions that are located and extend between the slots of wall 110. Top surface portion 180 (FIG. 3) forms the base of slot 160 and is located between wall portions 114A and 114B. Top surface portion 181 (FIG. 3) forms the base of slot 162 and is located between wall portions 114C and 114D. Top surface portion 182 (FIG. 3) forms the base of slot 164 and is located between wall portions 114E and 114F. Top surface portion 183 (FIG. 3) forms the base of slot 166 and is located between wall portions 114G and 114H.

The filter 10 has a plurality of resonators 25 (FIGS. 2 and 3) defined in part by a plurality of metallized through-holes. Specifically, resonators 25 take the form of through-holes 30 (FIGS. 2 and 3) which are defined in dielectric core 12. Through-holes 30 extend from and terminate in openings 34 (FIGS. 2 and 3) in top surface 14 and openings (not shown) in bottom surface 16. Through-holes 30 are aligned in a spaced-apart, co-linear relationship in block 12 such that through-holes 30 are equal distances from sides 18 and 20. Each of through-holes 30 is defined by an inner cylindrical metallized side-wall surface.

Top surface 14 of core 12 additionally defines a surface-layer recessed pattern 40 of electrically conductive metallized and insulative unmetallized areas or patterns. Pattern 40 is defined on the top surface 14 of core 12 and thus defines a recessed filter pattern by virtue of its recessed location at the base of cavity 150 in spaced relationship from and with the top rim 200 of walls 110, 120, 130, and 140.

The metallized areas are preferably a surface layer of conductive silver-containing material. Recessed pattern 40 also defines a wide area or pattern of metallization 42 (FIGS. 2 and 3) that covers at least bottom surface 16, side surfaces 18, 22 and 24, and the outside surfaces 111, 121, 131, and 141 and top rim 200 of each of the walls 110, 120, 130, and 140. Wide area of metallization 42 also covers a portion of top surface 14 and side surface 20 and the interior side walls of through-holes 30. Metallized area 42 extends contiguously from within resonator through-holes 30 towards both top surface 14 and bottom surface 16. Metallization area 42 may also be labeled a ground electrode. Area 42 serves to absorb or prevent transmission of off-band signals. A more detailed description of recessed pattern 40 on top surface 14 follows.

For example, a portion of metallized area 42 is present in the form of resonator pads 60A, 60B, 60C, 60D, 60E and 60F (FIGS. 2 and 3) which surround respective through-hole openings 34 defined on top surface 14. Resonator pads 60A-F are contiguous or connected with metallization area 42 that extends through the respective inner surfaces 32 of through-holes 30. Resonator pads 60A-F at least partially surround the respective openings 34 of through-holes 30. Resonator pads 60A-F are shaped to have predetermined capacitive couplings to adjacent resonators and other areas of surface-layer metallization.

An unmetallized area or pattern 44 (FIGS. 2 and 3) extends over portions of top surface 14 and portions of side surface 20. Unmetallized area 44 surrounds all of the metallized resonator pads 60A-F.

Unmetallized area 44 extends onto top surface slot portions 180, 181, 182 and 183 (FIGS. 2 and 3). Unmetallized area 44 also extends onto side wall slot portions 114A, 114B, 114C, 114D, 114E, 114F, 114G and 114H (FIGS. 2 and 3). Side wall slot portions 114A and 114B define the opposed side walls of post 110B. Side wall slot portions 114F and 114G define the opposed side walls of posts 110D.

Unmetallized area 44 also defines an unmetallized area 49 which extends onto a portion of side surface 20 located below post 110B and slots 160 and 162 in a generally rectangular shape. A similar unmetallized area 48 extends onto a portion of side surface 20 located below post 110D and slots 164 and 166 in a generally rectangular shape. Unmetallized areas 44, 48 and 49 are co-extensive or joined or coupled with each other in an electrically non-conducting relationship.

Surface-layer pattern 40 additionally defines a pair of isolated metallized areas or strips for input and output connections to filter 10. An input connection area or strip or electrode 210 (FIGS. 2 and 3) and an output connection area or strip or electrode 220 (FIGS. 2 and 3) are defined on top surface 14 and extend onto a portion of wall 110 and side surface 20 and, more specifically, onto the inner, rim, and outer portions of respective input and output posts 110D and 110B where they can serve as surface mounting connection points as described in more detail below. Electrode 210 is located adjacent and parallel to filter side surface 22 while electrode 220 is located adjacent and parallel to filter side surface 24.

Elongated input connection area of metallization or electrode 210 is located adjacent side surface 22. Input connection area or electrode 210 includes electrode portions 211, 212, 213 and 214 (FIGS. 2 and 3). Electrode portion 211 is located between resonator pads 60E and 60F and connects with electrode portion 212 that is located on inner surface portion 112D of post 110D. Electrode portion 212 connects with electrode portion 213 that is located on the top rim portion of post 110D. Electrode portion 213 connects with electrode portion 214 that is located on the outer surface 111 of post 110D. Electrode portion 214 is surrounded on all sides by unmetallized areas 44 and 48 (FIGS. 2 and 3).

Generally Y-shaped output connection area of metallization or electrode 220 is located adjacent side surface 24. Output connection area or electrode 220 includes electrode portions 221, 222, 223 and 224, 226 and 227 (FIGS. 2 and 3). Electrode portion or finger 221 is located between resonator pads 60A and 60B, extends in a generally parallel relationship to side 24 and connects with electrode portion 226 that is located on inner surface portion 112B of post 110B. Electrode portion 226 connects with electrode portion 227 that is located on the top rim portion of post 110B. Electrode portion 227 connects with electrode portion 224 that is located on the outer surface 111 of post 110B. Electrode portion 224 is surrounded on all sides by unmetallized areas 44 and 49 (FIG. 2).

Another electrode portion 222 (FIGS. 2 and 3) is located between resonator pads 60A and 60B and extends in a generally parallel relationship to side 24. Electrode portion 222 is L-shaped and connects with electrode finger 223 (FIG. 2) that extends into a U-shaped unmetallized area 52 that is substantially surrounded by resonator pad 60B. An unmetallized area 225 (FIG. 2) is located between electrode portions 221 and 222.

Lid Filter

FIGS. 1 and 4-6 depict one embodiment of the lid, cover or plate filter 820 in accordance with the present invention which is mounted to monoblock filter 10 to form a composite RF filter assembly 800 with improved attenuation and signal rejection characteristics when compared to the performance of filter 10 alone.

Lid filter 820 comprises a generally elongate, parallelepiped or flat shaped rigid slab or plate comprised of a ceramic dielectric material having a desired dielectric constant. In one embodiment, the dielectric material can be a barium or neodymium ceramic with a dielectric constant of about 12 or above. Lid filter 820 defines an outer surface with six generally rectangular sides: a top side or top surface 826; a bottom side or bottom surface 828 that is parallel to and diametrically opposed from top surface 826; a first side or side surface 830; a second side or side surface 832 that is parallel to and diametrically opposed from side surface 830; a third side or end surface 834; and a fourth side or end surface 836 that is parallel to and diametrically opposed to end surface 834. Plate 820 and the respective side surfaces thereof additionally define a plurality of vertical peripheral edges 838 and a plurality of horizontal peripheral edges 839 (FIG. 4).

A generally rectangularly-shaped recess or groove 840 is defined in side 832 (FIG. 4) and is located adjacent side surface 836. Recess 840 separates lid 820 from post 110B (FIG. 1) and defines a gap 842 (FIG. 1) around post 110B.

A low pass filter 848 is defined on top surface 826 of plate 820 by a surface-layer pattern 850 of electrically conductive metallized and insulative unmetallized areas or patterns (FIGS. 1 and 4).

The metallized areas are preferably a surface layer of conductive silver-containing material. Pattern 850 is defined in part by generally square-shaped metallized pads 851 and 852 (FIG. 4) that are located on a portion of top surface 826 adjacent side surface 834. Pads 851 and 852 are spaced from each other and separated by an unmetallized slot or region 857. A plurality of strips of conductive material define arms 853, 854 and 855 (FIG. 4) that form a C-shape and connect pads 851 and 852 to each other. Arm 854 is connected to pad 851 and arm 855 is connected to pad 852. Arm 853 is connected between arms 854 and 855. A generally rectangularly-shaped unmetallized area or region 856 is defined in the interior region bounded by arms 853, 854, 855 and pads 851 and 852. Region 856 is contiguous and perpendicular to region 857 and together define a generally T-shaped unmetallized region or area.

A strip or line of metallization 858 connects the pad 851 to a metallized connection pad 860. Connection pad 860 extends partially on top surface 826; wraps over the back horizontal edge 839 onto back side 830 (FIG. 5); and connects to a wide area of metallization 880 (FIG. 6) on the bottom surface 828 of lid filter 820.

A strip or line of metallization 859 connects pad 852 to metallized connection pad 862. Connection pad 862 extends partially on top surface 826; wraps over front horizontal edge 839 onto side 832 and then onto bottom surface 828 (FIG. 6) to define a conductive RF signal input/output connection pad on the bottom surface 828 which is surrounded by a generally U-shaped unmetallized area 864 (FIG. 6).

As described above, pattern 850 defines a wide area or pattern of metallization 880 (FIG. 5) that covers all of bottom surface 828 except for the area 864 surrounding connection pad 862. Wide area or pattern of metallization 880 also covers a portion of top surface 826 and side surfaces 830, 832 and 834.

More specifically, wide area of metallization 880 comprises: a rectangularly-shaped metallized area 870 (FIG. 4) adjacent side surface 834 that covers a portion of top surface 826 adjacent side surface 834; a metallized area 871 that covers a portion of side surface 830 (FIG. 5) adjacent side surface 834; a metallized area 872 (FIGS. 4 and 6) that covers a portion of side surface 832 adjacent side surface 834; and a metallized area 873 (FIGS. 4 and 5) that covers the entirety of side surface 834.

Pattern 850 further includes an unmetallized area 890 that extends over portions of top surface 826, bottom surface 828, and at least portions of side surfaces 830, 832, and 836.

Referring back to FIG. 1, lid filter 820 is mounted to filter 10 such that lid 820 covers cavity 150. Specifically, lid 20 is mounted on top of the walls 110, 120, 130, and 140 and, more specifically, the peripheral circumferential edge of the bottom surface 828 of lid filter 820 is supported and seated on the rim 200 of walls 110, 120, 130 and 140 in a relationship spaced from and parallel to the top surface 14 of filter 10.

Because rim 200 is metallized and portions of bottom surface 828 are covered by wide area of metallization 880, lid filter 820 can be attached to filter 10 by the use of a solder material. Solder 894 can be screen printed onto portions of the lid filter 820, placed onto the rim 200, and then reflowed in an oven to connect the lid 820 to filter 10.

Solder 896 can also be placed onto connection pad 862 on bottom surface 828 of the lid filter 820. Connection pad 862 is seated on the top rim portion of the post 110D and connected to the top rim portion 213 of the electrode 214 thereon and then reflowed to make an electrical connection between the connection pad 862 and electrode 214 and thus between the low pass filter 848 on the lid filter 820 and the filter 10.

Low pass filter 848 on lid filter 820 is also connected to wide area of metallization (or ground) 42 on filter 10 via connection pad 860 on lid filter 820 which is coupled to the wide area of metallization 880 on the bottom surface 828 of the lid filter 820 which, in turn, is in contact with the metallization on the top rim 200 of the wall 120 which, in turn, is coupled to the wide area of metallization 42 on filter 10.

It is understood of course that other means or methods may be used to couple the lid filter 820 to the filter 10 including, for example, using a conductive epoxy instead of solder or using a co-firing method in which the filters 10 and 820 are fired together in a silver firing furnace after the lid filter 820 has been seated on top of the filter 10.

FIG. 7 is a graph of signal strength (or loss) versus frequency demonstrating a specific measured performance of filter assembly 800 including low pass filter 848 in accordance with the present invention. Low pass filter 848 provides additional suppression of harmonic frequencies outside the pass band of filter 10. FIG. 7 shows a graph of return loss (S11) and insertion losses (S12) and (S21) for the frequencies measured between the input and output electrodes for a range of harmonic frequencies up to 12 GHz.

The use of filter assembly 800 has many advantages. By mounting low pass filter 848 on filter 10, space is saved on the printed circuit board to which filter 10 is mounted. With low pass filter 848 and filter 10 coupled together, the composite filter assembly 800 can be tuned as a single unit to provide an improved electrical match. Low pass filter 848 allows for filtering of harmonic frequencies in excess of 12 GHz. Other type of filters such as notch filters, band pass filters and band stop filters could also be formed on lid filter 820 using various metallization patterns. Other components may also be formed or mounted on lid 820. For example, a delay line, coupler, amplifier, LC filter or mixer could be formed on lid filter 820.

Alternative Lid Filter Embodiment

FIGS. 8, 9, and 10 depict an alternative embodiment of a lid, cover or plate filter 920 that can be mounted to monoblock filter 10 in place of the lid filter 820 to form the composite filter assembly 800.

Lid filter 920 comprises a generally elongate, parallelepiped or flat shaped rigid slab or plate comprised of a ceramic dielectric material having a desired dielectric constant. In one embodiment, the dielectric material can be a barium or neodymium ceramic with a dielectric constant of about 12 or above.

Lid filter 920 defines an outer surface with six generally rectangular sides: a top side or top surface 926; a bottom side or bottom surface 928 that is parallel to and diametrically opposed from top surface 926; a first side or side surface 930; a second side or side surface 932 that is parallel to and diametrically opposed from side surface 930; a third side or end surface 934; and a fourth side or end surface 936 (FIG. 8) that is parallel to and diametrically opposed from end surface 934.

Lid filter 920 and the respective side surfaces thereof additionally define a plurality of vertical peripheral edges 938 and a plurality of horizontal peripheral edges 939.

A low pass filter 948 is defined on the top surface 926 of lid filter 920 by a surface-layer pattern 950 of electrically conductive metallized and insulative unmetallized areas or patterns.

The metallized areas are preferably a surface layer of conductive silver-containing material. Pattern 950 initially is defined by square-shaped metallized pads 951 and 952 that are generally centrally located on top surface 926. Pads 951 and 952 are spaced and separated from each other by a region of unmetallized material defining a slot 957. Pads 951 and 952 are connected together by elongated metallized arms 953, 954 and 955 (FIG. 7) that form a C-shape. Arm 954 is connected to pad 951 and arm 955 is connected to pad 952. Arm 953 is connected between arms 954 and 955. A generally rectangularly-shaped unmetallized area or region 956 is defined between arms 953, 954, 955 and pads 951 and 952. Region 956 is contiguous and perpendicular to region 957 and together define a generally T-shaped unmetallized area.

An elongate strip or line of metallization 960 extends generally centrally on the top surface 926 from arm 955 in the direction of side surface 934 in an orientation parallel to side surfaces 930 and 932; wraps over the horizontal edge 939 onto side surface 934; and is electrically connected to a wide area of metallization 980 (FIGS. 9 and 10) on bottom surface 928.

Another elongate strip or line of metallization 962 on top surface 926 extends from arm 954 initially in the direction of side surface 936 and then bends ninety degrees and extends toward side surface 932; wraps over the horizontal edge 939 onto side surface 932; and then onto the bottom surface 928 and terminates to define an RF signal input/output connection pad 963 (FIG. 10) which is surrounded on bottom surface 928 by a generally U-shaped unmetallized area or region 964.

As described above, pattern 950 defines a wide area or pattern of metallization 980 that covers the entire bottom surface 928 except for the unmetallized region 964 surrounding the metallized connection pad 963. Wide area or pattern of metallization 980 also covers a portion of top surface 926 and side surfaces 930, 932 and 934.

Wide area of metallization 980 includes respective diametrically opposed generally rectangularly-shaped metallized areas 970 and 973 (FIG. 8) that cover a portion of top surface 926 adjacent side surface 934. Area 970 is located in the lower right corner of top surface 926 while area 973 is located in the lower left corner of top surface 926 in a diametrically opposed relationship to area 970.

Wide area of metallization 980 also includes a metallized area 971 (FIG. 9) that covers a portion of side surface 930 adjacent side surface 934 and a metallized area 974 (FIGS. 8 and 9) that covers a portion of side surface 934 adjacent side surface 930. Metallized areas 971 and 974 connect area 973 to metallized area 980 on the bottom surface 928 of lid filter 920.

A metallized area 972 (FIGS. 8 and 10) covers a portion of side surface 932 adjacent side surface 934 and a metallized area 976 covers a portion of side surface 934 adjacent side surface 932. Metallized areas 972 and 976 connect area 970 to the metallized area 980 on the bottom surface 928 of lid filter 920.

Pattern 950 further defines an unmetallized area 990 (FIG. 8) that extends over portions of top surface 926, bottom surface 928, and portions of side surfaces 930, 932, 934 and 936.

Lid filter 920 is mounted to monoblock filter 10 in the same manner as the lid filter 820 shown in FIG. 1, i.e., in a manner spaced from and parallel to the top surface 14 of filter 10; covering the cavity 150 of filter 10; and supported on and seated against the top metallized rim 200 of walls 110, 120, 130 and 140 of filter 10.

As with the lid filter 820, because the rim 200 of the walls 110, 120, 130, and 140 of filter 10 are metallized and portions of the bottom surface 928 of lid filter 920 are covered by wide area of metallization 980, lid filter 920 can be attached to filter 10 by the use of a solder material. An electrical connection between connection line 962 on lid filter 920 and electrode 224 on filter 10 can be made using the solder material.

Low pass filter 948 is thus connected at one end to electrode 224 on the post 1108 of filter 10 via connection line 962 and, more specifically, the connection pad portion 963 of connection line 962 on the bottom surface 928 of lid filter 920 which is seated against and coupled to the post 110B and, more specifically, against the top rim electrode portion 227 (FIG. 2) of the electrode 224. At the other end, low pass filter 948 is connected to the wide area of metallization (or ground) 42 of filter 10 via connection line 960 and, more specifically, the portion thereof which wraps around the side surface 934 of lid filter 920 into contact with the wide area of metallization 980 on bottom surface 928 which, in turn, is seated over and in contact with the metallization which covers the top rim 200 of the wall 140 of the filter 10.

Lid filter 920 would also be seated against the top rim of the post 110D in a relationship with the electrode portion 213 on the top rim of post 110D is in contact with the wide area of metallization 980 on the bottom surface 928 of the lid filter 920.

Numerous variations and modifications of the monoblock and lid embodiments described above may be effected without departing from the spirit and scope of the novel features of the invention.

For example only, it is understood that the core 12 and respective walls extending upwardly from the top surface 14 may be structured so that the cavity 150 occupies less than the full top surface 14 of the core 12 such as, for example, only the region surrounding the input/output posts 110B and 110D and resonator pads 60A and 60D.

It is also to be understood that no limitations with respect to the specific lid filter embodiments illustrated herein are intended or should be inferred. It is, of course, intended to cover by the appended claims all such modifications as fall within the scope of the claims.

Claims

1. A filter comprising: a block of dielectric material including: one or more through-holes;a plurality of surfaces including a top surface;one or more walls of dielectric material extending upwardly from the top surface;a region of conductive material on the block of dielectric material extending onto one or more of the walls of the block and defining at least a first input/output pad on one of the walls; anda plate of dielectric material including: first and second opposed surfaces;an area of conductive material on one of the first and second surfaces defining at least a first input/output pad;a pattern of conductive material on one of the first or second surfaces coupled to the first input/output pad on the one of the first or second surfaces;the plate being seated on one or more of the walls of the block in a spaced relationship from the top surface of the block, the first input/output pad on the one of the walls of the block coupled to the first input/output pad on the plate.

2. The filter of claim 1, wherein the region of conductive material on the block extends from the top surface of the block onto one or more of the walls of the block and defines first and second input/output pads on one or more of the walls of the block, the lid defining a recess surrounding the second input/output pad on the one or more of the walls of the block.

3. The filter of claim 1, wherein the plate includes front and back side surfaces, the first input/output pad being defined on the first surface of the plate and the pattern of conductive material being defined on the second surface of the plate and including a first strip of conductive material wrapping around the front side surface of the plate and terminating in the first input/output pad on the first surface of the plate, and a second strip of conductive material on the second surface of the plate wrapping around the back side surface of the plate and terminating in a wide area of conductive material on the first surface of the plate.

4. The filter of claim 1, wherein the plate includes a front surface and a side surface, the first input/output pad being defined on the first surface of the plate and the pattern of conductive material being defined on the second surface of the plate and including a first strip of conductive material wrapping around the front surface of the plate and terminating in the first input/output pad on the first surface of the plate, and a second strip of conductive material on the second surface wrapping around the side surface of the plate and terminating in a wide area of conductive material on the first surface of the plate.

5. A filter assembly comprising: a first filter defined by a block of dielectric material including a top surface, a plurality of through-holes, and at least a first post of dielectric material extending upwardly from the top surface of the block and including a region of metallization thereon defining at least a first input/output pad; anda second filter defined by a plate of dielectric material including opposed first and second surfaces, a wide area of metallization defined on the first surface, and a pattern of metallization defined on the second surface coupled at one end to a first input/output pad on the first surface of the plate and coupled at an opposite end to the wide area of metallization on the first surface of the plate;the plate being coupled to the block in a relationship seated on the first post and spaced from the top surface of the block with the first input/output pad on the first surface of the plate in contact with the first input/output pad on the first post.

6. The filter assembly of claim 5, wherein the block includes at least first and second posts of dielectric material extending from the top surface, the plate defining a recess surrounding the second post.

7. A filter assembly comprising: a first filter defined by a block of dielectric material including at least a top surface, a plurality of through-holes extending through the block, a wall of dielectric material extending upwardly from the top surface and defining a top peripheral rim, first and second posts of dielectric material extending upwardly from the top surface of the block, and a region of metallization defined on at least the top surface, the top peripheral rim of the wall, and the first and second posts to define respective first and second input/output pads on the first and second posts; anda second filter defined by a plate of dielectric material including opposed top and bottom surfaces, a wide area of metallization defined on the bottom surface, and a pattern of metallization defined on the top surface of the plate coupled at one end to a first input/output pad on the bottom surface of the plate and coupled at an opposite end to the wide area of metallization defined on the bottom surface of the plate;the plate being coupled in a spaced relationship from the block and seated against the top peripheral rim of the wall of the block, the input/output pad on the bottom surface of the plate being in contact with one of the first and second posts on the block and the wide area of metallization on the bottom surface of the plate being in contact with the region of metallization on the top peripheral rim of the wall of the block.

8. The filter assembly of claim 7, wherein the first post on the block is in contact with the input/output pad on the bottom surface of the plate and the second post on the block is spaced from the plate.

9. The filter assembly of claim 7, wherein the second post on the block is in contact with the input/output pad on the bottom surface of the plate and the first post on the block is in contact with the wide area of metallization on the bottom surface of the plate.

10. The filter assembly of claim 7, wherein the plate includes a plurality of side surfaces, a first strip of metallization extending over the top surface and one of the side surfaces of the plate into coupling relationship with the first input/output pad on the bottom surface of the plate and a second strip of metallization extending over the top surface and another of the side surfaces of the plate into coupling relationship with the wide area of metallization defined on the bottom surface of the plate.

11. The filter assembly of claim 10, wherein the plate includes front and back side surfaces, the first strip of metallization extending over the front side surface and the second strip of metallization extending over the back side surface.

12. The filter assembly of claim 10, wherein the plate includes front and back side surfaces, the first strip of metallization extending over the front side surface.