A multi-layer LC resonance balun includes at least a section of broadside coupled lines connected to an input port and two balanced output ports through transmission lines. Each section of coupled lines has two coupled lines. The first embodiment has at least two sections of coupled lines connected to a transmission line and coupled in parallel with at least one capacitor. The coupled lines are connected to an input port and two balanced output ports. The second embodiment has at least a section of coupled lines coupled in parallel with capacitors and then connected to an input port and two balanced output ports through transmission lines. By means of a multiple layer dielectric structure and meandered coupled lines, the size of the blaun is decreased and the frequency bandwidth is increased.

FIELD OF THE INVENTION

The present invention generally relates to a balance-to-unibalance transformer (blaun) used in a wireless local network or personal communication, and more specifically to a multi-layer LC resonance balun that can be fabricated as a device in a micro-chip.

BACKGROUND OF THE INVENTION

A balun is a device for converting signals between an unbalanced circuit structure and a balanced circuit structure. The signal of a balanced circuit structure comprises two signal components with same magnitude but 180-degree phase difference. Many analog circuits require balanced inputs and outputs in order to reduce noise and high order harmonics as well as improve the dynamic range of the circuits.

There are several types of baluns that are either active or passive. Passive baluns can be classified as lumped-type, coil-type and distributed-type baluns. A lumped-type balun uses lumped capacitors and inductors to match impedance and generate two balanced signals with same magnitude and 180-degree phase difference. The advantages of a lumped-type balun are small volume and light weight. However, it is not easy to maintain the 180-degree phase difference and the identical magnitude between the two signals.

Coil-type baluns have been widely used in lower frequency and ultra high frequency (UHF) bands. When a coil-type balates is used in higher than the UHF band, it usually has a drawback of having considerable loss. In addition, it has reached the limit of miniaturization and can not be further reduced in size.

Distributed-type baluns can further be classified as 180-degree hybrid and Marchand. A 180-degree hybrid balun has a fairly good frequency response in the microwave frequency band. However, its size often poses a problem when it is used in the radio frequency range between 200 MHz and several GHz. Because a 180-degree hybrid balun comprises a few sections of quarter wave transmission lines, it is difficult to reduce the size. Even if it is manufactured in a meandered way, a significant area is still required. One approach to reducing the size is to use a power divider along with a pair of transmission lines having different length for generating the 180-degree phase difference. Nevertheless, the size is still too large.

As shown in FIG. 1 , a Marchand balun commonly used in the industry comprises two sections of quarter wave coupled lines. This type of baluns has a fairly large bandwidth. Both phase balance and power distribution of a Marchand balun are reasonably good. However, the transmission lines in a Marchand balun need to be tightly coupled in order to achieve a sufficient bandwidth. Therefore, a Marchand balun is often broadside coupled to reduce its area. It is also fabricated in a meandered way to minimize its size. The balun is commonly seen in an RF application. Using a high dielectric constant material can also reduce the size of a Marchband balun.

U.S. Pat. No. 5,497,137 discloses a chip-type transformer as shown in FIG. 2 . The chip-type transformer comprises a laminate 200 formed by five dielectric substrates 214 a - 214 e superimposed one on the other. A ground electrode 216 is formed on a main surface of the first dielectric substrate 214 a . Another ground electrode 230 is formed on a main surface of the fifth dielectric substrate 214 e . A connecting electrode 220 is formed on a main surface of the second dielectric substrate 214 b.

There is a first strip line 222 on the third dielectric substrate 214 c . The first strip line 222 comprises a first spiral portion 224 a and a second spiral portion 224 b that are electromagnetically coupled respectively to a second strip line 226 and a third strip line 228 formed on the fourth dielectric substrate 214 d . The structure of the chip-type balun is broadside coupled and miniaturized by means of a high dielectric constant material. However, its size can not be reduced to a chip size if a low dielectric constant material is used.

SUMMARY OF THE INVENTION

This invention has been made to overcome the above-mentioned drawbacks of conventional baluns. The primary object is to provide a multi-layer balun having an equivalent circuit of an LC resonator. The equivalent circuit comprises at least a section of coupled lines, at least a transmission line and at least a capacitor. By means of the multi-layer structure and meandered coupled lines, the size of the balun of this invention is greatly reduced. In addition, the baluns can be realized with low dielectric constant materials to increase their stability.

According to this invention, the coupled lines of one of the embodied baluns have a symmetric structure with respect to a center geometrically. Both responses of magnitude and phase are well balancing. By adjusting the length of the coupled lines and the capacitance values, the impedance at the balanced output ports can be properly matched.

In a first embodiment, the equivalent circuit of the LC resonance balun comprises two sections of coupled lines connected to a transmission line trimming section and a parallel capacitor. By increasing the capacitance value of the parallel capacitor, the size of the balun can be reduced. Using a multi-layer structure, the capacitor may be fabricated on dielectric layers below or above the coupled lines. A vertically stacked multi-layer structure greatly reduces the size of the balun.

In a second embodiment, the equivalent circuit of the blaun comprises a section of coupled lines connected in parallel with two capacitors. The two ends of coupled lines are connected to an input port and two balanced output ports through transmission lines. The equivalent length of one LC resonator connected to the input port is shorter than a quarter of the wavelength. The equivalent length of the other LC resonator connected to the output ports is shorter than a half of the wavelength.

In the preferred embodiments of this invention, multiple sections of coupled lines can be incorporated. The coupled lines are manufactured with winding lines such as spiral lines, meandered lines, sinusoidal lines or saw-tooth lines. By means of winding lines, the area of the coupled lines is reduced. Multiple capacitors can also be used to increase the capacitance value. Based on the simulation, the balun of this invention shows that in a 200 MHz frequency bandwidth centered at 2.44 GHz, the magnitude difference is less than 2 dB and the 180-degree phase difference is less than 5 degrees at the two balanced ports.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 3 a shows the equivalent circuit of the LC resonator 300 of an LC resonance balun according the first embodiment to this invention. The equivalent circuit comprises two sections of broadside coupled lines 301 and 302 that are much shorter than a quarter of the wavelength, a trimming section of transmission line 303 and a capacitor 304 connected in parallel.

The first section of broadside coupled lines includes two coupled lines 301 a and 301 b , and the second section of broadside coupled lines includes two coupled lines 302 a and 302 b . Coupled line 301 b has one end connected to the ground 777 and the other end connected through a metal line 313 b to a first balanced port 312 b . Similarly, coupled line 302 b has one end connected to the ground 777 and the other end connected through a metal line 313 a to a second balanced port 312 a.

The transmission line trimming section 303 has a first end connected through a strip line 314 a to one end of the coupled line 301 a , and a second end connected through a strip line 314 b to one end of the coupled line 302 a . An unbalanced port 311 which is connected to one end of a coupled line 302 a through a strip line 306 is an input terminal. As shown in FIG. 3 a , the coupled transmission lines have completely symmetric structures on two sides with respect to the center geometrically. Both phase and magnitude are well balanced at the balanced ports. By adjusting the capacitance of the capacitor 304 and the length of the coupled lines, the impedance at the balanced ports can be matched properly. Because of the multi-layer structure, there are parasitic capacitances 305 a and 305 b between the embedded capacitor 304 and ground plane 777 .

In practice, the broadside coupled lines in the first embodiment can be a symmetric or asymmetric structure. The transmission line trimming section 303 can be capacitive or inductive. In addition to increasing the balance between the balanced ports, it can also match the impedance between the balanced and unbalanced ports when the impedance of the balanced ports has a complex value. The LC resonator in this embodiment may also be extended to include multiple sections of broadside coupled lines and multiple capacitors connected in parallel as illustrated in FIG. 3 b.

As can be seen in FIG. 3 b , a plurality of sections of broadside coupled lines are connected to section 301 and section 302 on the two sides. Each section of coupled lines comprises first and second coupled lines. Each first coupled line of the middle sections 32 i is connected in series, and each second coupled line of the middle sections 32 i is connected in series on one side. The middle sections 32 j on the other side are connected similarly.

The most left section 321 has its first coupled line 321 a connected through the strip line 306 to the unbalanced port 311 , and its second coupled line 321 b connected to the ground 777 . The first coupled line 321 a is also connected to a plurality of parallel capacitors C l -C n that are connected to the first coupled line 320 a of the most right section 320 . The second coupled line 320 b of the most right section 320 is connected to the ground 777 . Similar to the FIG. 3 a , parasitic capacitances 305 a and 305 b also exist between these embedded parallel capacitors C l -C n and ground plane 777 .

According to this invention, by properly increasing the capacitance of the parallel capacitors in the equivalent circuit, the size of the device can be reduced. It is also possible to move half of the symmetric structure above the capacitors to form a structure which is also symmetric from top to bottom. The capacitors may be located above or below the coupled lines. The balanced ports may be formed in other dielectric layers by using via holes for connection. A symmetric structure extending upwards and downwards can be formed to take advantage of a multi-layer structure and to reduce the size of the balun significantly. Further detail will be described later with reference to FIGS. 6 a and 6 b.

FIG. 4 a shows the equivalent circuit of the LC resonator 400 of a second preferred embodiment of an LC resonance balun according to this invention. The equivalent circuit comprises a section 401 of two broadside coupled lines 401 a and 401 b , two capacitors 403 and 404 respectively connected in parallel with the two coupled lines 401 a and 401 b , and two pairs of transmission lines 411 a , 411 b , 412 a and 412 b.

Transmission line 401 a of one LC resonator has one end connected to an unbalanced port 413 through the transmission line 411 a , and the other end to the ground 777 through the transmission line 411 b . The length of total transmission lines is smaller than a quarter of the wavelength. Two ends of transmission line 401 b of the other LC resonator are connected to two balanced ports 414 a and 414 b through two transmission lines 412 a and 412 b respectively. The length of total transmission lines is smaller than one half of the wavelength. Because of the multi-layer structure, there are parasitic capacitances 405 a , 405 b and 406 a , 406 b among the embedded capacitors 403 , 404 and ground plane 777 .

By means of the theory of an LC resonator, the structure of the second embodiment can effectively reduce the size of the balun. The impedance matching as well as the balance of the phase and magnitude at the balanced ports can be achieved by properly designing the length of the two transmission lines 412 a and 412 b . Similar to the first embodiment, the broadside coupled lines may have a symmetric or asymmetric structure in realization. Moreover, multiple sections of coupled lines and multiple parallel capacitors may be used to extend the structure of this embodiment.

As shown in FIG. 4 b , a plurality of sections of broadside coupled lines are connected to the two sides of the section 401 . Each section of coupled lines comprises first and second coupled lines. Each first coupled line of the middle sections is connected in series, and each second coupled line of the middle sections is connected in series. The first coupled lines of the most right and left sections are connected through the transmission lines 412 a and 412 b to the balanced port 414 a and 414 b respectively. The second coupled line of the most left section is connected through the transmission line 411 a to the unbalanced port 413 . The second coupled line of the most right section is connected through the transmission line 411 b to the ground 777 . A plurality of capacitors 403 - 1 , 403 - 2 , . . . , 403 -m and 404 - 1 , 404 - 2 , . . . , 404 -n are connected in parallel with the plurality of sections of the broadside coupled lines. Similar to the FIG. 4 a , parasitic capacitances 405 a , 405 b and 406 a , 406 b also exist among these embedded parallel capacitors 403 - 1 , 403 - 2 , . . . , 403 -m, 404 - 1 . 404 - 2 , . . . , 404 -n and ground plane 777 .

In the preferred embodiments of this invention, the coupled lines may be formed by several different ways. FIGS. 5 a - 5 d illustrate four different examples for the coupled lines including spiral lines, meandered lines, sinusoidal lines and saw-tooth lines. By means of these winding lines, the size of the balun can be reduced.

FIGS. 6 a and 6 b illustrate multi-layer device structures for baluns having equivalent circuits as described in FIGS. 3 a and 3 b . The multi-layer structures increase the values of the parallel capacitors in the equivalent circuits. The coupled lines are formed by spiral lines. One capacitor is connected in parallel with two sections of broadside coupled lines. In FIG. 6 a , the capacitors are located on the left side of the broadside coupled lines. In FIG. 6 b , the capacitors are located below the broadside coupled lines. In order to increase the length of broadside coupled lines for achieving broader frequency bandwidth, balanced ports are formed in other layers and connected by via holes as shown in FIGS. 6 a and 6 b.

In FIG. 6 a , the balun comprises eight vertically stacked dielectric layers 612 a - 612 h . The main surfaces of the first and eighth dielectric layers 612 a , 612 h are the first and second ground planes for the device as illustrated by slanted lines. These ground planes are formed by a metallic material. A via hole 615 a and a first output port 620 a are formed on the second dielectric layer 612 b . The range of the first output port 620 a is from the center to the upper right edge of the main surface. On the seventh dielectric layer 612 g is another via hole 615 b and a second output port 620 b . The range of the second output port 620 b is from the center to the upper left edge of the main surface.

The first section of broadside coupled lines are formed on the third and fourth dielectric layers 612 c , 612 d . The first and second coupled lines 624 a , 624 b of the first section are fabricated respectively with spiral lines on the right side of the main surfaces of the third and fourth dielectric layers. The first electrode CP 1 of a capacitor and an input port 630 are also fabricated on the fourth dielectric layer 612 d . The capacitor electrode CP 1 is connected to the second coupled line 624 b and located on the left side of the first section of broadside coupled lines. One end of the first coupled line 624 a is connected to the first output port 620 a and the other end is connected to the ground plane 612 a through the via hole 615 a.

Similar to the first section of broadside coupled lines, the first and second coupled lines 626 a , 626 b of the second section are fabricated respectively with spiral lines on the right side of the main surfaces of the sixth and fifth dielectric layers 612 f , 612 e . The second electrode CP 2 of a capacitor is also fabricated on the fifth dielectric layer 612 e . The capacitor electrode CP 2 is connected to the second coupled line 626 b and located on the left side of the second section of broadside coupled lines. One end of the first coupled line 626 a is connected to the second output port 620 b and the other end is connected to the ground plane 612 h through the via hole 615 b . Although the capacitor formed by CP 1 and CP 2 is located on the left side of the first and second sections of broadside coupled lines in the embodiment illustrated in FIG. 6 a , it can also be located on the right side in practice.

The balun structure shown in FIG. 6 b comprises eleven dielectric layers 642 a - 642 k because the two capacitor electrodes CP 1 and CP 2 are formed in separate dielectric layers below the first and second sections of broadside coupled lines. The main surfaces of the first and eleventh dielectric layers 642 a , 642 k are the first and second ground planes for the device as illustrated by slanted lines. A third ground plane with two via holes is formed on the eighth dielectric layer 642 h . The first section of broadside coupled lines are formed with first and second spiral lines 624 a , 624 b on the third and fourth dielectric layers 642 c , 642 d respectively. The second section of broadside coupled lines are formed with first and second spiral lines 626 a , 626 b on the sixth and fifth dielectric layers 642 f , 642 d respectively.

The first and second output ports 620 a , 620 b are formed on the second and seventh dielectric layers 642 b , 642 g respectively. The two capacitor electrodes CP 1 and CP 2 that are connected respectively to the spiral lines 626 b and 624 b through via holes on the eighth dielectric layer 642 h are formed on the ninth and tenth dielectric layers 642 i , 642 j . As can be seen in FIG. 6 b , the spiral line 624 a has one end connected to the first output port 620 a and the other end connected to the first ground plane on the first dielectric layer 642 a . Similarly, the spiral line 626 a has one end connected to the second output port 620 b and the other end connected to the third ground plane on the eighth dielectric layer 642 h . Although the capacitor formed by CP 1 and CP 2 is located below the first and second broadside coupled lines in the embodiment illustrated in FIG. 6 b , it can also be located above the first and second sections of broadside coupled lines in practice.

FIG. 7 illustrates a multi-layer device structure for baluns having equivalent circuits as described in FIGS. 4 a and 4 b . The balun shown in FIG. 7 comprises nine dielectric layers 712 a - 712 i stacked vertically. The main surfaces of the first and ninth dielectric layers 712 a , 712 i are the first and second ground planes for the device as illustrated by slanted lines. The capacitor electrode CP of a first capacitor is fabricated on a main surface of the second dielectric layer 712 b . The first and second capacitor electrodes CP 1 , CP 2 of a second capacitor are fabricated on the main surfaces of the seventh and eighth dielectric layers 712 g , 712 h respectively.

A section of broadside coupled lines comprises a first spiral line 724 a and a second spiral line 724 b formed on the main surfaces of the fourth and fifth dielectric layers 712 d , 712 e respectively. Transmission lines 732 a , 732 b are formed on the main surface of the fifth dielectric layer 712 e and the transmission line 746 is formed on the main surface of the second dielectric layer 712 b . It should be noted that the transmission line 411 b shown in FIG. 4 a can be omitted in realization.

Between the section of broadside coupled lines and the capacitors are the third and fourth ground planes formed on the third and sixth dielectric layers 712 c , 712 f . A via hole 715 a is formed on the main surface of the third dielectric layer 712 c and two via holes 715 b and 715 c are formed on the main surface of the sixth dielectric layer 712 f.

In the present invention, the preferred material for forming the coupled lines, transmission lines or ground planes is a low loss metallic material such as Ag, Pd, Cu, Au, or Ni. Assuming a ceramic dielectric constant r 7.8 and a center frequency f 0 2.44 GHz, the operating efficiency of the baluns of this invention are analyzed based on the multi-layer circuit structures shown in FIGS. 3 a and 4 a . The characteristics for the return loss S 11 as well as the insertion losses S 21 and S 31 are measured and shown in FIGS. 8 a and 9 a for the circuits of FIGS. 3 a and 4 a respectively. In the figures, the vertical axis is the magnitude of the measured loss in dB. The horizontal axis shows the operating frequency of the balun from 2 to 3 GHz.

In a high frequency circuit, the measured voltage and current are fluctuated like waves whose values may vary with locations. To characterize a circuit using the scattering parameter (S parameter), the impedance characteristic of the transmission line connected to each port has to be preset. The return loss S 11 should be less than 10 dB in the designed frequency range, i.e., 2.34-2.54 GHz. As can be seen from FIGS. 8 a and 9 a , the return loss is less than 10 dB which means that the balun has good impedance match and the energy loss is very small. As far as the insertion losses S 21 and S 31 , the energy should be distributed equally in the two ports with some loss due to the material. The loss shown in FIGS. 8 a and 9 a is less than 3 dB which indicates that the energy has been equally distributed and the balanced ports receive most of the energy.

FIGS. 8 b and 9 b show the measured differences in magnitude and phase within the operating frequency range for the two circuits. The horizontal axis is the operating frequency of the balun in GHz. The vertical axis shows the differences in degree and dB for phase and magnitude respectively. As can be seen, within an operating frequency range 200 MHz, the magnitude difference is less than 2 dB and the phase difference is less than 5 degrees.

According to the multi-layer LC resonance balun of the invention, the drawbacks of the conventional baluns have been overcome. The size of the device has been significantly reduced and the operating frequency bandwidth is increased. The device can be fabricated by materials with a low dielectric constant. In addition to the reduction in cost, the stability of the device is also improved. Therefore, the baluns of this invention can be fabricated with a micro-chip size and suitably used in a wireless network or personal communication.