KR100273636B1 - Apparatus for separating transmitting signal and receiving signal - Google Patents

Abstract

In the present invention, a transmission / reception separator of the present invention in a frequency-differential transmission / reception frequency portable terminal and a transmission / reception splitter are provided. A dielectric capacitor and a capacitor having a capacitive impedance value that cancels the inductive impedance value of the first transmission linear ceramic dielectric resonator at the first resonant frequency are connected in series, and a transmission frequency is connected between the receiver side and the antenna. An inductive impedance value that offsets the capacitive impedance value of the second transmission linear ceramic dielectric resonator having the second resonance frequency near the center of the band and the second transmission linear ceramic dielectric resonator at the second resonance frequency Branch inductors are connected in series.

Description

Transceiver separator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable terminal apparatus, and more particularly, to a transmission and reception separation apparatus in a frequency and time division multiple access terminal having different transmission and reception frequencies.

In a general mobile terminal, as shown in FIG. 1, a transmission and reception separation device 4 is provided at the rear end of the antenna 2 so that the transmission signal and the reception signal can pass to their paths while sharing the antenna. The transmission and reception separator 4 is connected to a transmitter and a receiver of the portable terminal, respectively.

Transmitting / receiving apparatus of a portable terminal of a time division multiple access method and a frequency different from the transmit / receive separation apparatus among the transmit / receive splitters include an antenna switch as shown in FIG. 2 and a duplexer as shown in FIG. 3. Is widely used.

First, referring to FIG. 2, the PIN diodes D1 and D2 are turned on or off based on a control voltage provided by a controller of the portable terminal. The PIN diodes D1 and D2 are turned on in the transmit mode and off in the receive mode. When the PIN diodes D1 and D2 are turned on in the transmission mode, the impedance of the PIN diodes D1 and D2 becomes very small, so that there is little loss on the transmitter side, and the λ / 4 transmission line 6 is opened by the short-circuit PIN diodes D1 and D2. Because of the open characteristic, the transmission signal does not go to the receiver but goes to the antenna. When the PIN diodes D1 and D2 are turned off in the reception mode, the received signals received through the antenna are not sent to the transmitter by the turned off PIN diodes D1 and D2.

When using the antenna switch shown in Figure 2 has the following disadvantages. A control voltage (current number mA) is required, and a control line connected to the portable terminal controller is required in order for the control voltage to be applied. In addition, harmonics are generated due to nonlinear operation of the PIN diode, and the usable characteristics are limited to the low frequency band (about 1 GHz band) compared to the passive element. Therefore, a signal loss occurs in a frequency band (about 2 GHz band) of an ICO (Intermediate Circular Orbit) terminal, which is an example of a portable terminal of a time division multiple access method and a frequency having different transmission and reception frequencies.

Next, a duplexer which is another example of a transmission / reception apparatus will be described with reference to FIG. 3. The duplexer forms multiple LC filters using dielectric resonators 8a, 8b, 8c, 8d, 8e, and 8f as inductors as shown in FIG. In the multiple LC filter, the band pass filtering bands for the transmission frequency and the reception frequency are determined differently, so the transmission and reception signals are separated.

However, when using the duplex shown in Figure 3 has a disadvantage that the size is large and the loss is large. Although the transmit / receive separation is very good, it is not suitable for frequency and time division multiple access mobile terminals that do not require high transmit / receive separation.

Accordingly, an object of the present invention is to provide a transmission and reception separation device suitable for a portable terminal of a frequency and time division multiple access method having different transmission and reception frequencies.

Another object of the present invention is to provide a transmission and reception separation device for reducing signal loss in a portable terminal of a time division multiple access method and a frequency having different transmission and reception frequencies.

In accordance with the above object, the present invention provides a transmission and reception separation apparatus in a time-division multiple access type portable terminal having a different transmission / reception frequency, wherein a first resonant frequency is located near the center of the reception frequency band of the portable terminal between a transmitter and an antenna. Is connected in series with a capacitor having a capacitive impedance value that cancels the inductive impedance value of the first transmission linear ceramic dielectric resonator in which the first transmission linear ceramic dielectric resonator is present and the first transmission linear ceramic dielectric resonator at the first resonance frequency. Cancels the capacitive impedance value of the second transmission linear ceramic dielectric resonator having a second resonant frequency near the center of the transmission frequency band between the antenna and the antenna and the second transmission linear ceramic dielectric resonator at the second resonance frequency. Inductor with inductive impedance value of about It shall be.

In addition, the present invention is a transmission and reception separation apparatus in a time-division multiple-access mobile terminal with a frequency different from the transmission and reception frequency, the first resonant frequency is present between the transmitter side and the antenna near the center of the reception frequency band of the portable terminal A transmission linear ceramic dielectric resonator and an inductor having an inductive impedance value to the extent that cancels the capacitive impedance value of the first transmission linear ceramic dielectric resonator at the first resonant frequency are connected in series, and between the receiver side and the antenna. Capacitive enough to cancel the inductive impedance value of the second transmission linear ceramic dielectric resonator having a second resonance frequency near the center of the transmission frequency band and the second transmission linear ceramic dielectric resonator at the second resonance frequency. It is characterized in that the capacitor having an impedance value is connected in series.

1 is a view showing the positional relationship of the transmission and reception separation apparatus.

FIG. 2 is a circuit diagram illustrating an antenna switch as an example of the transmission / reception apparatus of FIG. 1.

3 is a circuit diagram illustrating a duplexer as another example of the transmission / reception separator of FIG. 1.

4 is a diagram illustrating a transmission / reception frequency band used by an ICO terminal, which is an example of a portable terminal having different transmission / reception frequencies.

5 is a circuit diagram of a transmission and reception separation device applied to a portable terminal having a transmission and reception frequency band as shown in FIG. 4 according to an embodiment of the present invention.

6 is a resonance frequency of the transmission linear dielectric resonators 10 and 12 of FIG. f _r1 and f _r2 Drawing showing range.

FIG. 7 is an equivalent circuit diagram of a transmission line ceramic dielectric resonator 10 and a capacitor C1 connected to a transmitter in the circuit configuration of FIG. 5.

FIG. 8 is an equivalent circuit diagram of a transmission linear ceramic dielectric resonator 12 and an inductor L1 connected to a receiver in the circuit configuration of FIG. 5. FIG.

9A and 9B are frequency characteristic curve diagrams according to the circuit configuration of FIG.

10 is a circuit diagram of a transmission and reception separation device applied to a portable terminal when the transmission frequency band is higher than the reception frequency band.

11 is a resonant frequency of a transmission linear dielectric resonator 10 and 12 of FIG. f _r1 and f _r2 Drawing showing range.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the same elements in the figures are denoted by the same numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

In the present invention, the separation of the transmitting and receiving terminals in portable terminals having different transmission and reception frequencies is less important than in other systems, and thus, the signal loss in transmitting and receiving signals is reduced by using two transmission linear resonators.

4 is a diagram illustrating a transmission / reception frequency band used by an ICO terminal, which is an example of a portable terminal having different transmission / reception frequencies, and the reception frequency band is higher than the transmission frequency band. 4, the transmission frequency band of the ICO terminal is 1985MHz ~ 2015MHz and the reception frequency band is 2710MHz ~ 2200MHz.

5 is a circuit diagram of a transmission and reception separation device applied to a portable terminal when the reception frequency band is higher than the transmission frequency band according to an embodiment of the present invention. Referring to Figure 5, the resonance frequency between the transmitter and the node 14 connected to the antenna f _r1 The transmission linear ceramic dielectric resonator 10 and the capacitor C1 near the center of the reception frequency band (2710 MHz to 2200 MHz) are connected in series, and a resonance frequency is provided between the node 14 connected to the receiver and the antenna. f _r2 The transmission linear ceramic dielectric resonator 12 and the inductor L1 near the center of the transmission frequency band (1985 MHz to 2015 MHz) are connected in series. The circuit configuration of FIG. 5 corresponds to a case where the reception frequency band of the portable terminal is higher than the transmission frequency band. That is, the resonance frequency of the transmission linear ceramic dielectric resonator 10,12 f _r1 , f _r2 end f _r2 < f _r1 If you are in a relationship.

In FIG. 6, the resonance frequencies of the transmission linear dielectric resonators 10 and 12 of FIG. f _r1 and f _r2 It is showing the range. Referring to FIG. 6, the resonance frequency of a transmission linear ceramic dielectric resonator 10 positioned between a transmitter and an antenna f _r1 Is the center frequency of the receiving frequency band f _or Resonant Frequency of Transmission-Line Ceramic Dielectric Resonator 12 in the Range (= 2185MHz) to ± 5MHz and Located Between Receiver and Antenna f _r2 Is the center frequency of the transmission frequency band f _ot It is in the range ± 5 MHz at (= 2000 MHz).

Returning to FIG. 5, the transmission linear ceramic dielectric resonators 10 and 12 are short-circuited (plated) with end faces, and thus the resonant frequency. f _r1 , f _r2 Has a very large characteristic impedance at (basic characteristic).

The transmission linear ceramic dielectric resonator 10 used on the transmitter side has a resonance frequency. f _r1 Since it is in the receiving frequency band, even if capacitor C1 is connected in series, the receiving frequency band shows a very large impedance characteristic and blocks the receiving signal. If the capacitor C1 is selected as an appropriate value, the transmission frequency shows a very small impedance (serial RLC resonance characteristic) at the transmission frequency, and the transmission signal transmitted from the transmitter passes through the antenna at low loss.

The transmission linear ceramic dielectric resonator 12 used on the receiver side has a resonance frequency. f _r2 Since is in the transmission frequency band, even though the inductor L1 is connected in series, it shows a very large impedance characteristic in the transmission frequency band and blocks the transmission signal. When the inductor L1 is selected as an appropriate value, the reception frequency shows a very small impedance (serial RLC resonance characteristic) at the reception frequency, and the received signal received through the antenna is passed through with low loss to the receiver.

FIG. 7 is an equivalent circuit diagram of a transmission line ceramic dielectric resonator 10 and a capacitor C1 connected to a transmitter in the circuit configuration of FIG. 5, and FIG. 8 is a transmission line ceramic dielectric resonator 12 and an inductor L1 connected to a receiver in the circuit configuration of FIG. 5. Equivalent circuit diagram for. 9A and 9B are diagrams illustrating a frequency characteristic curve according to the circuit configuration of FIG. 5.

5 and 7 to 9a, b will be described in detail the principle and operation of the transmission and reception signal separation according to an embodiment of the present invention.

First, referring to FIG. 7, in the circuit configuration of FIG. 5, the equivalent circuit viewed from the transmitter side includes an impedance Zr1 (= Re + Im) of the transmission line ceramic dielectric resonator 10 and an impedance (conductance) of the capacitor C1. And load resistance Z _L according to the antenna side connection. Therefore, the total impedance Z1 viewed from the transmitting side is expressed by Equation 1 below.

Z1 = Z _r1 -jX _C + 50 [Ω]

9A is a frequency characteristic curve diagram of an equivalent circuit viewed from the transmitter side. Real component of impedance (Zr ₁ ) component of transmission linear ceramic dielectric resonator 10 Re [Zr ₁ ] Resonant frequency f _r1 Has infinite value in, imaginary component Im [Zr ₁ ] Resonant frequency f _r1 Has an inductive impedance value and the resonance frequency f _r1 Thereafter, it has a capacitive impedance value.

Referring to FIG. 7 and FIG. 9A together, the frequency f is a resonance frequency near the center of the reception frequency band. f _r1 Becomes (f = f _r1 ), The value of impedance Zr ₁ becomes very large. In other words, Re [Zr ₁ ] → ∞ to be. Therefore, the impedance of capacitor C1 -jX _C And load resistance Z _L are negligible. Therefore, the overall impedance (Z) Z1 ≈ Zr ₁ = ∞ Becomes This means that the reception frequency does not go to the transmitter. However, if the frequency f is a transmission frequency band, for example, f = f _r2 In the case of ± 15 MHz, the impedance Zr ₁ of the transmission linear ceramic dielectric resonator 10 has a value of l as shown in FIG. 9A. Therefore, the impedance (capacitance value) of capacitor C1 connected in series with the transmission linear ceramic dielectric resonator 10 As shown in Fig. 9A, when the value of -1 is selected, the magnitude of the total impedance Z1 seen from the transmitter side becomes very small. That is, the frequency f is the resonance frequency f _r1 At ± 15 MHz, the total impedance Z1 is Has a relationship with Even in Equation 1 described above Z _r1 = jX _C = l If left, the overall impedance (Z1) Z1 ≈ 50 [Ω] It can be seen that. This means that the transmission signal transmitted from the transmitter passes through the antenna with low loss.

Next, referring to FIG. 8, in the circuit configuration of FIG. 5, the equivalent circuit seen from the receiver side includes the impedance Zr2 (= Re + Im) of the transmission linear ceramic dielectric resonator 12 and the impedance of the inductor L1. jX _L (= jwL) And load resistance Z _L according to the antenna side connection. Therefore, the total impedance Z2 viewed from the receiving side is expressed by Equation 2 below.

Z2 = Z _r2 + jX _L + 50 [Ω]

9B is a frequency characteristic curve diagram of an equivalent circuit viewed from the receiver side. Real component of impedance (Zr ₂ ) component of transmission linear ceramic dielectric resonator 12 Re [Zr ₂ ] Resonant frequency f _r2 Has infinite value in, imaginary component Im [Zr ₂ ] Resonant frequency f _r2 Has an inductive impedance value and the resonance frequency f _r2 Thereafter, it has a capacitive impedance value.

8 and 9B, the resonant frequency where the frequency f is near the center of the transmission frequency band f _r2 Becomes (f = f _r1 ), The value of impedance Zr ₂ becomes very large. In other words, Re [Zr ₂ ] → ∞ to be. Therefore, the impedance of inductor L1 jX _L Overload resistance Z _L is negligible. Therefore, the overall impedance (Z2) Z2 ≈ Zr ₂ = ∞ Becomes This means that the transmission frequency does not go to the receiver. However, if frequency f is a reception frequency band, for example, f = f _r1 In the case of ± 15 MHz, the impedance Zr ₂ of the transmission linear ceramic dielectric resonator 12 has a value of -d as shown in FIG. 9B. Therefore, the impedance (inductance value) of inductor L1 connected in series with the transmission linear ceramic dielectric resonator 12 jX _L (= jwL) As shown in Fig. 9B, when d is selected to be d, the magnitude of the total impedance Z2 seen from the receiver side becomes very small. That is, the frequency f is the resonance frequency f _r1 At ± 15 MHz, the total impedance Z2 is Im [Z _r2 + jwL] → 0, Re [Z _r2 ] → 0 Has a relationship with Also in the above equation (2) Z _r2 = jX _L = d If left, the overall impedance (Z2) is Z2 ≈ 50 [Ω] It can be seen that. This means that the received signal received through the antenna passes through with low loss to the receiver.

On the other hand, the total loss caused by the transmission signal to the antenna is largely composed of a heat loss in the transmission linear ceramic dielectric resonator 10 on the transmitter side and a capacitor C1 connected in series with the dielectric resonator 10 and a loss to the receiver side. The heat loss decreases as the characteristic impedance of the transmission linear ceramic dielectric resonator 10 decreases, and is in inverse proportion to the resonance sharpness Q of the dielectric resonator 10 and the capacitor C1. The loss exiting to the receiver side is mainly inversely proportional to the resonance sharpness Q of the dielectric resonator 10 and inversely proportional to the characteristic impedance of the dielectric resonator 10. Therefore, although the two losses (heat loss and loss to the receiver side) show opposite characteristics to the characteristic impedance of the transmission linear ceramic dielectric resonator 10, the main loss is due to the capacitor C1 connected in series with the transmission linear ceramic dielectric resonator 10. It is preferable to keep the characteristic impedance of the resonator 10 at a low value in view of the size of the resonator. Although the transmission signal is mentioned above, the same interpretation as the transmission signal is applied to the reception signal.

5 according to an embodiment of the present invention corresponds to a case where the reception frequency band of the portable terminal is higher than the transmission frequency band. That is, the resonance frequency of the transmission linear ceramic dielectric resonator 10,12 f _r1 , f _r2 end f _r2 < f _r1 If you are in a relationship.

However, if the transmission frequency band of the portable terminal is higher than the reception frequency band, in the configuration of Figure 5 L1, C1 are interchanged with each other.

FIG. 10 illustrates a circuit configuration of a transmission / reception separator applied to a portable terminal when the transmission frequency band is higher than the reception frequency band. In FIG. 11, the resonance frequencies of the transmission linear dielectric resonators 10 and 12 of FIG. f _r1 and f _r2 It is showing the range.

10 and 11 together, the resonance frequency between the transmitter 14 and the node 14 connected to the antenna f _r1 The center root of this frequency band ( f _or A resonant frequency between the transmission linear ceramic dielectric resonator 10 at ± α MHz) and the inductor L2 in series, and the node 14 connected to the receiver and the antenna f _r2 Center root of the frequency band f _ot A transmission line ceramic dielectric resonator 12 at ± α MHz) and capacitor C2 are connected in series.

When the transmission frequency is higher than the reception frequency, it is understood that L1 and C1 are interchanged with each other according to an embodiment of the present invention with reference to FIGS. 9A and 9B. The impedance value of the capacitor C1 shown in FIG. 9A has a negative region due to its characteristics, and the impedance value of the inductor L1 shown in FIG. 9B has a positive region due to its characteristics. Therefore, if the transmission and reception frequency bands shown in Figures 9a, b are interchanged with each other it can be seen that the capacitor and the inductor should also be connected.

Transmission and reception separation apparatus according to an embodiment of the present invention can be used when the transmission and reception separation is not very important in the portable terminal of the frequency and time division multiple access method such as GSM terminal, ICO terminal. In addition, the low loss effect according to the embodiment of the present invention improves the receiver gain / noise temperature (G / T) and reduces the transmitter power amplifier output, thereby increasing the use time by improving the terminal power efficiency.

In the above description of the present invention, specific embodiments have been described, but various modifications can be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be defined by the equivalent of claims and claims.

As described above, the present invention exhibits stable characteristics by using a ceramic resonator having good temperature characteristics and improves the point that the antenna switch falls short of the specifications of the ICO terminal in the 2 GHz band, which is the frequency band of the ICO terminal. In addition, high power can be handled by using passive devices. In addition, the duplexer used in the frequency division duplex (FDD) system is improved in the size and loss that is applied to the frequency division and time division multiple access system.

Claims (8)

In a transmission / reception device in a frequency and time division multiple access type portable terminal having a different transmission / reception frequency, Inductive impedance of a first transmission linear ceramic dielectric resonator in which a first resonant frequency exists near a center of a reception frequency band of the portable terminal between a transmitter and an antenna, and an inductive impedance of the first transmission linear ceramic dielectric resonator at the first resonant frequency Capacitors with capacitive impedance values that cancel out the values are connected in series, A capacitive impedance value of a second transmission linear ceramic dielectric resonator having a second resonant frequency between the receiving side and the antenna near a center of a transmission frequency band and the second transmission linear ceramic dielectric resonator at the second resonant frequency are determined. Transceiving and separating device characterized in that the inductor having an inductive impedance value of the degree of cancellation is connected in series. The transmission / reception apparatus of claim 1, wherein the first and second transmission linear ceramic dielectric resonators have a short end surface. In a transmission / reception device in a frequency and time division multiple access type portable terminal having a different transmission / reception frequency, Capacitive impedance of a first transmission linear ceramic dielectric resonator in which a first resonant frequency exists near the center of a reception frequency band of the portable terminal between a transmitter and an antenna, and the first transmission linear ceramic dielectric resonator at the first resonant frequency Inductors with inductive impedance values that cancel out the values are connected in series, Inductive impedance values of a second transmission linear ceramic dielectric resonator having a second resonant frequency between a receiving side and the antenna near a center of a transmission frequency band and the second transmission linear ceramic dielectric resonator at the second resonant frequency are determined. Transceiving and separating apparatus, characterized in that the capacitor having a capacitive impedance value of the offset to be connected in series. The transmission / reception apparatus of claim 3, wherein the first and second transmission linear ceramic dielectric resonators have a short end surface. In a transmission / reception apparatus in a frequency and time division multiple access type portable terminal having a reception frequency band higher than a transmission frequency band, With antenna, With a transmitter, Receiving unit, A first transmission line ceramic dielectric resonator connected in series with the transmitter and having a first resonant frequency near a central portion of a reception frequency band of the portable terminal; A capacitor connected in series between the first transmission linear ceramic dielectric resonator and the antenna and having a capacitive impedance value that cancels the inductive impedance value of the first transmission linear ceramic dielectric resonator at the first resonant frequency; Wow, A second transmission line ceramic dielectric resonator connected in series with the receiver and having a resonance frequency near a central portion of a transmission frequency band of the portable terminal; An inductor connected in series between the second transmission linear ceramic dielectric resonator and the antenna and having an inductive impedance value that cancels the capacitive impedance value of the second transmission linear ceramic dielectric resonator at the second resonant frequency; Transmitting and receiving device characterized in that the configuration. 6. The transmission and reception device of claim 5, wherein the first and second transmission linear ceramic dielectric resonators have a short end surface. A transmission / reception apparatus in a frequency and time division multiple access type portable terminal in which a transmission frequency band is higher than a reception frequency band, With antenna, With a transmitter, Receiving unit, A first transmission line ceramic dielectric resonator connected in series with the transmitter and having a first resonant frequency near a central portion of a reception frequency band of the portable terminal; An inductor connected in series between the first transmission linear ceramic dielectric resonator and the antenna and having an inductive impedance value that cancels the capacitive impedance value of the first transmission linear ceramic dielectric resonator at the first resonant frequency; Wow, A second transmission line ceramic dielectric resonator connected in series with the receiver and having a resonance frequency near a central portion of a transmission frequency band of the portable terminal; A capacitor connected in series between the second transmission linear ceramic dielectric resonator and the antenna and having a capacitive impedance value that cancels the inductive impedance value of the second transmission linear ceramic dielectric resonator at the second resonant frequency; Transmitting and receiving device, characterized in that configured as. 8. The transmission / reception apparatus of claim 7, wherein the first and second transmission linear ceramic dielectric resonators have a short end surface.