This application claims priority from French Application for Patent No. 09-57028 filed Oct. 8, 2009, the disclosure of which is hereby incorporated by reference.
The present invention relates to the field of integrated-circuit semiconductor devices.
It appears to be particularly advantageous to have such semiconductor devices for transporting signals.
A semiconductor device is proposed that comprises a substrate on at least one face of which integrated circuits and an electrical connection network are formed.
The semiconductor device may further comprise at least one electromagnetic waveguide comprising two metal plates that are placed on either side of at least one part of the thickness of said substrate and are located facing each other and two longitudinal walls placed facing each other and formed by pluralities of metal vias made in holes passing through the substrate in its thickness direction and extending between said metal plates.
The semiconductor device may further comprise at least one electrode on the substrate, coupled electromagnetically to the electromagnetic waveguide and connected electrically to the integrated circuits by the electrical connection network.
The semiconductor device may further include at least one transverse wall at least at one of the ends of said longitudinal walls, this transverse wall being formed by a plurality of metal vias made in holes passing through the substrate in its thickness direction and extending between said metal plates.
The semiconductor device may further comprise at least one electrode made in a hole of said substrate and connected to at least one electronic component of said integrated circuits through a passage or opening in the metal plate located on the side with the integrated circuits, at a certain distance from the edge of this passage.
At least one of said metal plates may have at least one passage or an opening, said device comprising at least one electrode extending above and at a certain distance from this passage and connected to at least one electronic component of said integrated circuits.
The semiconductor device may further comprise at least one obstacle made in at least one hole of the substrate, this obstacle being placed inside the electromagnetic waveguide.
Semiconductor devices will now be described by way of non-limiting examples and illustrated by the drawing in which:
A semiconductor device 1 shown in
Integrated circuits 5 and an interconnect layer 6 are formed on the front face 3 of the substrate 2, in which interconnect layer an electrical connection network 7, for example on several metal levels connected by metal vias, is provided.
The device 1 further comprises an electromagnetic waveguide 8.
The structure of the electromagnetic waveguide 8 may comprise two metal plates 9 and 10 formed on either side of the opposed faces 3 and 4 of the substrate 2 and located facing each other. The metal plate 9 may be placed on the face 3 of the substrate 2 or in a metal level of the interconnect layer 6. According to this example, the integrated circuits 5 and the metal plate 9 are on different zones of the front surface 3 of the substrate 2.
The structure of the electromagnetic waveguide 8 may further comprise two longitudinal walls 11 and 12 facing each other and formed by pluralities of metal vias 13 and 14 respectively that are made in and fill holes 15 and 16 passing through the substrate 2 in its thickness direction and at a certain distance from each other. The metal vias 13 and 14 extend between the metal plates 9 and 10, from one metal plate to the other, adjacent to or in the proximity of two opposed edges of these plates.
According to the example shown, the metal vias 13, on the one hand, and the metal vias 14, on the other hand, may be aligned in such a way that the longitudinal walls 11 and 12 that they form are rectilinear. The distance between the metal vias 13 and the distance between the metal vias 14 may be approximately equal to λ/10. Furthermore, the longitudinal walls 11 and 12 may be parallel, their distance depending on the operating wavelength (λ), for example a wavelength of 430 microns for operation at 120 gigahertz.
The electromagnetic waveguide 8 therefore is in the form of a corridor.
The metal plates 9 and 10 may have passages or openings 17 and 18 facing one another, for example circular passages or openings.
According to one embodiment, the semiconductor device 1 may further comprise a metal electrode 19 immersed inside the electromagnetic waveguide 8.
This electrode 19 may be formed in a hole 20, for example a cylindrical hole, passing through the substrate 2 in the thickness direction and located in the central part of the opposed passages 17 and 18 of the metal plates 9 and 10, at a distance from the edges of these passages in such a way that the metal electrode 19 is electrically isolated from the electromagnetic waveguide 8.
The electrical connection network 7 comprises means 7a designed to connect the end of the metal electrode 19, located on the face 3 of the substrate 2, to an electronic component 5a of the integrated circuits 5 on the substrate 2.
The electromagnetic waveguide 8 may be electrically isolated or connected to a reference potential of the electronic component 5a by suitable means 7b of the electrical connection network 7.
It follows from the foregoing that, as regards an emitter, the electrode 19 may be capable of generating, in the electromagnetic waveguide 8, electromagnetic waves under the effect of radiofrequency signals coming from the electronic component 5a or, in terms of receiver, the electrode 19 may also be capable of receiving electromagnetic waves in the electromagnetic waveguide 8 in order to deliver radiofrequency signals to the electronic component 5a.
In one embodiment, the hole 20 that receives the electrode 19 could extend over part of the thickness starting from the face 3 of this substrate, the electrode 20 then being shorter. In this case, the plate 10 provided on the rear face 4 of the substrate 2 could not have the passage 18 and could be a solid plate.
According to another embodiment, illustrated in
This metal electrode 22 may extend above a central part of the passage 17 of the metal plate 9, for example passing from one side of it to the other, and may be connected to the electronic component 5a. In this example, the passage or opening 17 in the metal plate 9 is rectangular. The plate 10 may or may not have a passage 18.
As in the case of the semiconductor device 1, the metal electrode 22, connected to the electronic component 5a, may act as electromagnetic wave emitter or as electromagnetic wave receiver in the electromagnetic waveguide 8.
According to another embodiment, illustrated in
Therefore, electronic components of the integrated circuits 5, for example the electronic component 5a, could be produced on top of the zone of the local layer 24 that replaces the front plate 9.
According to another embodiment, illustrated in
The electromagnetic waveguide 27 also comprises metal plates, namely front and rear plates 28 and 29, which are rectangular and placed on either side of the substrate 26, facing each other, and opposed longitudinal walls 30 and 31 formed by pluralities of metal vias 32 and 33 made through the substrate 26 in through-holes 34 and 35 and located along the longitudinal edges of the front and rear metal plates 28 and 29 and between said metal plates.
According to this example, the electromagnetic waveguide 27 further comprises opposed transverse walls 36 and 37 formed by pluralities of metal vias 38 and 39 made through the substrate 26 in through-holes 40 and 41 and located along the transverse edges of the front and rear metal plates 28 and 29 and between said metal plates.
The electromagnetic waveguide 27 therefore takes the form of an elongated cage.
For example along its longitudinal axis, the front metal plate 28 has passages or openings 42 and 43 spaced apart longitudinally. The rear metal plate 29 may also have passages or openings 44 and 45 placed facing the passages 42 and 43.
The semiconductor device 25 further comprises electrodes 46 and 47 which, according to the example shown, each correspond to the electrode 19 of the example described with reference to
As in the example described with reference to
As in the example described with reference to
As illustrated in
According to one embodiment, the electrodes 46 and 47 could be replaced with the electrode 22 described with reference to
According to another embodiment, illustrated in
The electromagnetic waveguide 58 then takes the form of a longitudinal corridor closed at one of its ends and open at the other.
Thus, an electrode 60 of this semiconductor device 55, which is connected to an electronic component 61, as for example in
The devices as above described have the advantages that the integrated circuits, the connection networks and the electromagnetic waveguides are integrated on a unique substrate. In consequence, the devices are mechanically resistant, the electrical connection are direct and secured and the electrical leakages are minimized.
The present invention is not limited to the examples described above. Many alternative embodiments are possible, in particular by combining the examples described, without departing from the scope defined by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
09 57028 | Oct 2009 | FR | national |