BIASING CIRCUIT
20250266799 ยท 2025-08-21
Assignee
Inventors
Cpc classification
H01F2003/106
ELECTRICITY
International classification
Abstract
A biasing circuit includes a signal input terminal, a signal output terminal, a first inductor, and a second inductor. The first inductor is with one end connected to a node between the signal input terminal and the signal output terminal. The second inductor is with one end connected to an other end of the first inductor. The first inductor includes a core that is formed by a bulk of ferrite. The second inductor includes a core that is formed by a bulk of high permeability material.
Claims
1. A biasing circuit, comprising: a signal input terminal; a signal output terminal; a first inductor with one end connected to a node between the signal input terminal and the signal output terminal; and a second inductor with one end connected to an other end of the first inductor, wherein the first inductor includes a core that is formed by a bulk of ferrite, and the second inductor includes a core that is formed by a bulk of high permeability material.
2. A biasing circuit, comprising: a signal input terminal; a signal output terminal; a first inductor with one end connected to a node between the signal input terminal and the signal output terminal; and a second inductor with one end connected to an other end of the first inductor, wherein the first inductor includes a core that is formed by molding powder of high permeability material with carbon binder, and the second inductor includes a core that is formed by a bulk of high permeability material.
3. The biasing circuit according to claim 1, wherein the high permeability material has a specific permeability of higher than 500.
4. The biasing circuit according to claim 1, wherein the other end of the second inductor is grounded.
5. The biasing circuit according to claim 2, wherein the core of the first inductor is formed by molding powder of iron, iron-based nanocrystallized material, high-purity iron, permendur, or silicon steel with carbon binder.
6. The biasing circuit according to claim 1, wherein the core of the second inductor is formed by a bulk of pure iron, amorphous magnetic material, iron-based nanocrystallized material, high-purity iron, permendur, silicon steel, permalloy, or supermalloy.
7. The biasing circuit according to claim 2, wherein the high permeability material has a specific permeability of higher than 500.
8. The biasing circuit according to claim 2, wherein the other end of the second inductor is grounded.
9. The biasing circuit according to claim 2, wherein the core of the second inductor is formed by a bulk of pure iron, amorphous magnetic material, iron-based nanocrystallized material, high-purity iron, permendur, silicon steel, permalloy, or supermalloy.
Description
BRIEF DESCRIPTION OF DRAWINGS
[0018]
MODES FOR CARRYING OUT THE INVENTION
[0019] A description will now be given of an embodiment of the present invention referring to drawings.
[0020]
[0021] A signal (e.g. high frequency signal) is input to the signal input terminal (RFin) 2. A signal (e.g. high frequency signal) is output from the signal output terminal (RFout) 4. The node 6 is provided between the signal input terminal 2 and the signal output terminal 4.
[0022] One end of the first inductor 12 is connected to the node 6. The other end of the first inductor 12 and one end of the second inductor 14 are connected to the node 8. Accordingly, the other end of the first inductor 12 is connected with the one end of the second inductor 14. Also, the other end of the second inductor 14 is grounded.
[0023] It is noted that the first inductor 12 and the second inductor 14 each serve as a low pass filter. The cutoff frequency of the first inductor 12 is higher than the cutoff frequency of the second inductor 14.
[0024] The first inductor 12 includes a core that is formed by a bulk of ferrite or by molding powder of high permeability material (e.g. iron, iron-based nanocrystallized material, high-purity iron, permendur, or silicon steel) with carbon binder.
[0025] The second inductor 14 includes a core that is formed by a bulk of high permeability material (e.g. pure iron, amorphous magnetic material, iron-based nanocrystallized material, high-purity iron, permendur, silicon steel, permalloy, or supermalloy).
[0026] It is noted that the high permeability material above means material that is sensitively magnetized by an external magnetic field and has, for example, a specific permeability of higher than 500.
[0027] Next will be described an operation according to the embodiment of the present invention.
[0028] A signal that has a high frequency component fHin and a low frequency component fLin is input to the signal input terminal (RFin) 2. It is noted that the cutoff frequency of the first inductor 12 is lower than the frequency of the high frequency component fHin but higher than the frequency of the low frequency component fLin. On the other hand, the cutoff frequency of the second inductor 14 is lower than the frequency of the low frequency component fLin.
[0029] The high frequency component fHin passes through the node 6, provided to and reflected by the first inductor 12, and output as a high frequency component fHout from the signal output terminal (RFout) 4. Here, the core of the first inductor 12 is formed by a bulk of ferrite or by molding powder of high permeability material with carbon binder and thereby undergoes reduced eddy current loss.
[0030] The low frequency component fLin passes through the node 6 and the first inductor 12, provided to and reflected by the second inductor 14, passes through the first inductor 12 and the node 6, and output as a low frequency component fLout from the signal output terminal (RFout) 4.
[0031] In accordance with the embodiment of the present invention, the core of the first inductor 12 is formed by a bulk of ferrite or by molding powder of high permeability material with carbon binder and thereby undergoes reduced eddy current loss.
[0032] Additionally, in accordance with the embodiment of the present invention, the core of the second inductor 14, which is formed by a bulk of high permeability material, can have higher permeability and therefore higher inductance, whereby the inductor can have a lower cutoff frequency, compared to the core of the first inductor 12, which is formed by a bulk of ferrite or by molding powder of high permeability material with carbon binder.
[0033] In addition, since a component with a frequency higher than the cutoff frequency of the second inductor 14 is reflected by the second inductor 14 and output from the signal output terminal (RFout) 4, the frequency band on the low-frequency side of the output of the biasing circuit 1 becomes wider as the second inductor 14 has a lower cutoff frequency.
[0034] That is, in accordance with the embodiment of the present invention, since the second inductor 14 can have a lower cutoff frequency, the frequency band on the low-frequency side of the output of the biasing circuit 1 can become wider.
[0035] Note here that if a current flowed through the second inductor 14, the eddy current loss in the second inductor 14 would be increased. However, since the low frequency component fLin is reflected by the second inductor 14, no current substantially flows through the second inductor 14. The eddy current loss in the second inductor 14 can therefore be reduced (even though, unlike the first inductor 12, the core is not formed by a bulk of ferrite or by molding powder of high permeability material with carbon binder).
DESCRIPTION OF REFERENCE NUMERALS
[0036] 1 Biasing Circuit [0037] 2 Signal Input Terminal (RFin) [0038] 4 Signal Output Terminal (RFout) [0039] 6, 8 Nodes [0040] 12 First Inductor [0041] 14 Second Inductor [0042] MHin, fHout High Frequency Component [0043] fLin, fLout Low Frequency Component