Abstract: First no-electrode-forming areas where first wiring electrodes such as internal wiring electrodes and external connection terminals are not formed are set to ranges that overlap inductor components in a plan view of at least one of dielectric layers of a first substrate, and second no-electrode-forming areas where second wiring electrodes such as internal wiring electrodes and mounting electrodes are not formed are set to ranges that overlaps the inductor components in a plan view of at least one of dielectric layers of a second substrate. Accordingly, reduction of the inductance of the inductor components, which is caused by the first and second wiring electrodes crossing the magnetic field of the inductor components, can be suppressed. Therefore, the overall component size can be reduced without deteriorating the Q value of the inductor components by configuring an RF component with a stacking structure.

Abstract: An object is to provide a technique that can reduce the degradation in the characteristics of a transmitting filter by improving heat dissipation characteristics of a composite component having a stack structure. Since a transmitting filter is disposed in or on a first substrate 14, the heat generated in the transmitting filter is efficiently dissipated, for example, to an external module substrate 2 electrically connected to the first substrate 14. It is thus possible to reduce changes in the characteristics of the transmitting filter caused by a temperature rise. Thus, by improving heat dissipation characteristics of a composite component 10 having a stack structure, the degradation in the characteristics of the transmitting filter can be reduced.

Abstract: A non-reciprocal circuit device includes: a permanent magnet; a ferrite to which a direct current magnetic field is applied by the permanent magnet; and a plurality of center conductors disposed on the ferrite so as to intersect with one another with being insulated from one another. One ends of the respective center conductors serve as input-output ports, and other ends of the respective center conductors are connected to a ground. Capacitance elements are connected in parallel to the respective center conductors. The permanent magnet includes a first permanent magnet and a second permanent magnet. With respect to the first permanent magnet and the second permanent magnet, directions of respective direct current magnetic fields applied to the ferrite are opposite to each other, and there is a difference between temperature characteristics of respective residual magnetic flux densities.

Abstract: Favorable isolation characteristics are obtained over a wide band in a non-reciprocal circuit element. A non-reciprocal circuit element includes: a magnetic material 10 to which a DC magnetic field is applied by a permanent magnet; and a plurality of center electrodes disposed on the magnetic material 10 so as to intersect each other in an insulated state. Of the plurality of center electrodes, a first center electrode 21 is connected at one end thereof to a first input/output port P1, and a second center electrode 22 is connected at one end thereof to a second input/output port P2. A resistance element R is connected in series between the ports P1 and P2, and a phase-shift circuit (a parallel resonant circuit composed of an inductance element L5 and a capacitance element C5) is connected in series with the resistance element R.

Abstract: First no-electrode-forming areas where first wiring electrodes such as internal wiring electrodes and external connection terminals are not formed are set to ranges that overlap inductor components in a plan view of at least one of dielectric layers of a first substrate, and second no-electrode-forming areas where second wiring electrodes such as internal wiring electrodes and mounting electrodes are not formed are set to ranges that overlaps the inductor components in a plan view of at least one of dielectric layers of a second substrate. Accordingly, reduction of the inductance of the inductor components, which is caused by the first and second wiring electrodes crossing the magnetic field of the inductor components, can be suppressed. Therefore, the overall component size can be reduced without deteriorating the Q value of the inductor components by configuring an RF component with a stacking structure.

Abstract: An object is to provide a technique that can reduce the degradation in the characteristics of a transmitting filter by improving heat dissipation characteristics of a composite component having a stack structure. Since a transmitting filter is disposed in or on a first substrate 14, the heat generated in the transmitting filter is efficiently dissipated, for example, to an external module substrate 2 electrically connected to the first substrate 14. It is thus possible to reduce changes in the characteristics of the transmitting filter caused by a temperature rise. Thus, by improving heat dissipation characteristics of a composite component 10 having a stack structure, the degradation in the characteristics of the transmitting filter can be reduced.

Abstract: Favorable isolation characteristics are obtained over a wide band in a non-reciprocal circuit element. A non-reciprocal circuit element includes: a magnetic material 10 to which a DC magnetic field is applied by a permanent magnet; and a plurality of center electrodes disposed on the magnetic material 10 so as to intersect each other in an insulated state. Of the plurality of center electrodes, a first center electrode 21 is connected at one end thereof to a first input/output port P1, and a second center electrode 22 is connected at one end thereof to a second input/output port P2. A resistance element R is connected in series between the ports P1 and P2, and a phase-shift circuit (a parallel resonant circuit composed of an inductance element L5 and a capacitance element C5) is connected in series with the resistance element R.

Abstract: A two-port non-reciprocal circuit element includes a ferrite, a first central electrode disposed on the ferrite and including an end connected to an input port and another end connected to an output port, a second central electrode disposed on the ferrite so as to intersect the first central electrode while being electrically insulated from the first central electrode, the second central electrode including an end connected to the input port and another end connected to a ground port, a capacitor connected between the input port and the output port, a resistor connected between the input port and the output port, a capacitor connected between the output port and the ground port, an input terminal, and an output terminal. A capacitor is connected at least between the input port and the input terminal or between the output port and the output terminal, and a capacitor and an inductor are connected in series between the input terminal and the output terminal.

Abstract: A two-port non-reciprocal circuit element includes a ferrite, a first central electrode disposed on the ferrite and including an end connected to an input port and another end connected to an output port, a second central electrode disposed on the ferrite so as to intersect the first central electrode while being electrically insulated from the first central electrode, the second central electrode including an end connected to the input port and another end connected to a ground port, a capacitor connected between the input port and the output port, a resistor connected between the input port and the output port, a capacitor connected between the output port and the ground port, an input terminal, and an output terminal. A capacitor is connected at least between the input port and the input terminal or between the output port and the output terminal, and a capacitor and an inductor are connected in series between the input terminal and the output terminal.

Abstract: A non-reciprocal circuit element includes a permanent magnet, a microwave magnetic body to which a direct current magnetic field is applied by the permanent magnet, a first center electrode that is wrapped around the microwave magnetic body, is connected at one end to an input port, and is connected at another end to an output port, a second center electrode that is wrapped around the microwave magnetic body while intersecting with the first center electrode so as to be insulated from the first center electrode, is connected at one end to the output port, and is connected at another end to a ground port, a first matching capacitance connected between the input port and the output port in parallel with the first center electrode, a terminating resistance connected between the input port and the output port in parallel with the first center electrode, and a second matching capacitance connected between the output port and the ground port.

Abstract: A non-reciprocal circuit element includes a permanent magnet, a microwave magnetic body to which a direct current magnetic field is applied by the permanent magnet, a first center electrode that is wrapped around the microwave magnetic body, is connected at one end to an input port, and is connected at another end to an output port, a second center electrode that is wrapped around the microwave magnetic body while intersecting with the first center electrode so as to be insulated from the first center electrode, is connected at one end to the output port, and is connected at another end to a ground port, a first matching capacitance connected between the input port and the output port in parallel with the first center electrode, a terminating resistance connected between the input port and the output port in parallel with the first center electrode, and a second matching capacitance connected between the output port and the ground port.

Abstract: A nonreciprocal circuit element includes first and second center electrodes. On a ferrite to which a direct-current magnetic field is applied from a permanent magnet, the first and second center electrodes are insulated and intersect. First and second ends of the first center electrode are connected to an input port and an output port, respectively. First and second ends of the second center electrode are connected to the output port and a ground port, respectively. A first matching capacitor and a resistor are connected between the input port and the output port. A second matching capacitor is connected between the output port and the ground port. A parallel resonant circuit is connected in parallel to the resistor. A coupling element is connected between the parallel resonant circuit and another parallel resonant circuit including the first center electrode and the first matching capacitor so as to the parallel resonant circuits.

Abstract: A nonreciprocal circuit element includes first and second center electrodes. On a ferrite to which a direct-current magnetic field is applied from a permanent magnet, the first and second center electrodes are insulated and intersect. First and second ends of the first center electrode are connected to an input port and an output port, respectively. First and second ends of the second center electrode are connected to the output port and a ground port, respectively. A first matching capacitor and a resistor are connected between the input port and the output port. A second matching capacitor is connected between the output port and the ground port. A parallel resonant circuit is connected in parallel to the resistor. A coupling element is connected between the parallel resonant circuit and another parallel resonant circuit including the first center electrode and the first matching capacitor so as to the parallel resonant circuits.

Abstract: A nonreciprocal circuit device includes a ferrite to which a direct magnetic field is applied using permanent magnets, central electrodes arranged on the ferrite, and a circuit substrate. The first central electrode is made of conductive films, and the second central electrode is made of conductive films. Some of the conductive films of the second central electrode are arranged on the first main surface of the ferrite, and a conductive film of the first central electrode is arranged on the conductive films through an insulating film. Furthermore, another one of the conductive films of the first central electrode is arranged on the second main surface, and the remainder of the conductive films of the second central electrode are arranged through an insulating film on the conductive film.

Abstract: A nonreciprocal circuit device includes a ferrite to which a direct magnetic field is applied using permanent magnets, central electrodes arranged on the ferrite, and a circuit substrate. The first central electrode is made of conductive films, and the second central electrode is made of conductive films. Some of the conductive films of the second central electrode are arranged on the first main surface of the ferrite, and a conductive film of the first central electrode is arranged on the conductive films through an insulating film. Furthermore, another one of the conductive films of the first central electrode is arranged on the second main surface, and the remainder of the conductive films of the second central electrode are arranged through an insulating film on the conductive film.

Abstract: A two-port non-reciprocal circuit device has one end of a first central electrode electrically connected to an input port and the other end thereof electrically connected to an output port. One end of a second central electrode is electrically connected to the output port and the other end thereof is electrically connected to a ground port. A resonant capacitor and a terminating resistor are electrically connected in parallel between the input port and the output port. A resonant capacitor is electrically connected between the output port and the ground port. Matching capacitors for impedance matching are electrically connected between the input port and an input terminal and between the output port and an output terminal, respectively. A coupling capacitor element is electrically connected between the input terminal and the output terminal.

Abstract: A two-port non-reciprocal circuit device has one end of a first central electrode electrically connected to an input port and the other end thereof electrically connected to an output port. One end of a second central electrode is electrically connected to the output port and the other end thereof is electrically connected to a ground port. A resonant capacitor and a terminating resistor are electrically connected in parallel between the input port and the output port. A resonant capacitor is electrically connected between the output port and the ground port. Matching capacitors for impedance matching are electrically connected between the input port and an input terminal and between the output port and an output terminal, respectively. A coupling capacitor element is electrically connected between the input terminal and the output terminal.

Abstract: A two-port isolator includes a microwave ferrite member, first and second center electrodes that intersect with each other on the ferrite member with isolation therebetween, a permanent magnet that applies a DC magnetic field to the ferrite member, and a multilayer substrate having center-electrode-connecting electrodes and first and second matching capacitors. The ferrite member, the first and second center electrodes, the permanent magnet, and the multilayer substrate are accommodated in a housing that includes a magnetic cap and a case having a magnetic metal plate molded thereonto. The second matching capacitor has a higher Q factor than the first matching capacitor.

Abstract: A two-port isolator includes a microwave ferrite member, first and second center electrodes that intersect with each other on the ferrite member with isolation therebetween, a permanent magnet that applies a DC magnetic field to the ferrite member, and a multilayer substrate having center-electrode-connecting electrodes and first and second matching capacitors. The ferrite member, the first and second center electrodes, the permanent magnet, and the multilayer substrate are accommodated in a housing that includes a magnetic cap and a case having a magnetic metal plate molded thereonto. The second matching capacitor has a higher Q factor than the first matching capacitor.

Abstract: A nonreciprocal circuit device which can be connected to a balanced circuit without going through a balun, and a communication device which includes the nonreciprocal circuit device. An isolator generally includes a circuit board, a lower metal case, a center electrode assembly, an upper metal case, a permanent magnet, a resistor, and matching capacitors. The circuit board comprises an insulating substrate, such as a glass epoxy substrate or a ferrite substrate, on which are formed an unbalanced input terminal, balanced output terminals (i.e., differential output terminals), a grounding terminal, and a half-wave line which interconnects the balanced output terminals.