KR100565299B1 - Triplexer circuit for tri-mode mobile station - Google Patents

Abstract

The present invention improves insertion loss and isolation characteristics by combining several passive elements without using a single filter in a tri-mode terminal that simultaneously handles various modes such as CDMA, GPS, and US-PCS. The present invention relates to a triplexer circuit of a tri-mode terminal that effectively separates signals between bands, and to a triplexer circuit for dividing a signal received through an antenna into three frequency bands (first, second, and third frequency bands). A first resonator comprising: a first resonator unit, one end of which is connected to an antenna and rejects a frequency band signal other than the first frequency band; A second resonator connected to the other end of the first resonator to pass only a first frequency band signal; Third and fifth resonators connected to the antenna in parallel with the first resonator to reject signals other than a second frequency band; Fourth and sixth resonator parts connected to the third and fifth resonator parts and the other end of the fifth resonator part, respectively, and allow only a second frequency band signal to pass therethrough; The third frequency band signal can be achieved by separating an inductor connected to the antenna in parallel with the third resonator and a filter connected in series with the other end of the inductor.

Description

TRIPLEXER CIRCUIT FOR TRI-MODE MOBILE STATION}

1 is a circuit diagram showing the configuration of a triplexer circuit of a tri-mode terminal according to the present invention.

FIG. 2 is a graph showing insertion loss, return loss, and attenuation characteristics for each frequency band in the circuit of FIG. 1. FIG.

3 is a graph showing separation characteristics in each frequency band in the circuit of FIG.

4 is a Smith chart showing the output impedance characteristics in each frequency band according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: first resonator 101: second resonator

102: third resonator 103: fourth resonator

104: fifth resonator 105: sixth resonator

106: GPS Saw Filter

The present invention relates to a triplexer circuit of a tri-mode terminal, and more particularly, in a tri-mode terminal that simultaneously processes various modes such as CDMA, GPS, and US-PCS, by combining several passive elements without using a single filter. The present invention relates to a triplexer circuit of a tri-mode terminal that effectively separates signals between frequency bands by improving insertion loss and separation characteristics.

The conventional dual band terminal has a diplexer capable of receiving and separating two different frequency bands (CDMA, PCS) through one antenna, so that signals having two frequency bands can be processed together. Recently, three frequency bands (US-PCS: 1850 ~ 1990MHz (F1), GPS: 1570 ~ 1580MHz (F2), CDMA: 824MHz ~ 894MHz) (F3)) is proceeding in a triple-band (Triple-band) method that can be processed separately.

In the frequency range of the triplexer, which is applied to a tri-mode terminal, the band is selected using two methods.

First, using RF switch and diplexer in SPDT format, first distribute F1 and F2 by RF switch and then F3 by diplexer or F1 and F3 by RF switch Next, F2 is distributed by the next diplexer, and second, frequency is distributed by using an active device.

As described above, in the case of a triplexer for simultaneously processing various modes such as CDMA, GPS, and US-PCS, these days are almost implemented as chips.

However, as the number of modes to be implemented in the terminal increases as described above, it is difficult to manufacture a single unit filter for simultaneously filtering various signals because the frequency interval between modes is close. In addition, in the case of GPS and US-PCS, the frequency spacing is about 300 MHz, which makes it difficult to manufacture a diplexer and a triplexer for signal separation.

Accordingly, the present invention was created to solve the above-mentioned conventional problems, and in a tri-mode terminal which simultaneously processes various modes such as CDMA, GPS, and US-PCS, several passive (Passive) devices are not used. It is an object of the present invention to provide a triplexer circuit of a tri-mode terminal that effectively separates signals between frequency bands by combining elements to improve insertion loss and isolation characteristics.

In order to achieve the above object, the present invention provides a triplex circuit for separating a signal received through an antenna into three frequency bands (first, second, and third frequency bands), one end of which is connected to the antenna Ant. A first resonator for rejecting signals other than the first frequency band; A second resonator connected to the other end of the first resonator to pass only a first frequency band signal; Third and fifth resonators connected to the antenna in parallel with the first resonator to reject signals other than a second frequency band; Fourth and sixth resonator parts connected to the third and fifth resonator parts and the other end of the fifth resonator part, respectively, and allow only a second frequency band signal to pass therethrough; And a third frequency band signal separated by an inductor connected to the antenna in parallel with the third resonator and a filter connected in series with the other end of the inductor.

The present invention is to provide a triplexer circuit that separates three frequency bands by combining only GPS saw filter and passive elements, and may be implemented as a multilayer frequency separation circuit using the discrete circuit according to the present invention. It can also be applied as a MMIC using a chipset.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described.

Fig. 1 is a circuit diagram showing the configuration of a triplexer circuit of a tri-mode terminal according to the present invention. First, the antenna Ant converts the power high frequency energy of the transmitter into radio wave energy at the time of transmission to radiate it into the space, and at the time of reception, It receives the radio wave energy of and converts it into electric power and supplies it to each receiver circuit.

Accordingly, the signal received through the antenna (Ant) is a CDMA frequency band (824MHz ~ 894MHz), GPS frequency band (1570MHz ~ 1580MHz) by the GPS saw filter, US PCS frequency band through the triplexer circuit of the present invention (1850 MHz to 1990 MHz).

Referring to FIG. 1, the present invention includes a first resonator 100 connected to an antenna Ant, a second resonator 101 connected to the other end of the first resonator 100, and A third resonator 102 connected to the antenna Ant in parallel with a first resonator, and fourth, fifth, and sixth resonators sequentially connected to the other end of the third resonator 102 in sequence; 103 to 105, an inductor L4 connected to the antenna Ant in parallel with the third resonator 102, and a saw filter unit 106 connected to the other end of the inductor L4. It is.

The CDMA band frequency is separated through the first and second resonators 100 and 101, and the US PCS band frequency is separated through the third to sixth resonators 102 to 105, and the inductor L5 is separated. ) And the Saw filter unit 106 separate the GPS band frequency.

The first resonator 100 serves as a band rejection to the short resonator in which the capacitor C2 and the inductor L2 are connected in parallel, and one end of the second resonator 101 is the first resonator. An inductor L6 connected to the output terminal of 100, a capacitor C4 connected to the other end of the inductor L6, and an inductor L5 connected to the other end of the capacitor C4 and the other end thereof grounded. The open resonator is configured to select a band. That is, the first and second resonators selectively output only CDMA band frequencies in the signal received through the antenna Ant.

In other words, the capacitor and the inductor connected in parallel to each other form an open resonance shape to select a desired band in the high frequency band, and the short resonator serves to reject a band other than the desired band.

Similarly, the third resonator 102 is connected by the capacitor C1 and the inductor L1 connected in parallel, and the fifth resonator 104 is the short resonator by the capacitor C6 and the inductor L8 connected in parallel. The fourth resonator 103 is connected to the capacitor C3 and the inductor L3 connected in parallel, and the sixth resonator 105 is connected to the capacitor C5 and the inductor in series. L7) results in an open resonator. That is, the third to sixth resonators selectively output only the US PCS band frequency from the signal received through the antenna Ant.

In addition, the series-connected inductor L4 and the saw filter unit 106 selectively output only the GPS band frequency in the signal received through the antenna Ant.

To do this, select C1 = 7pF, C2 = 1pF, C3 = 2pF, C4 = 4pF, C5 = 4pF, C6 = 7pF, C7 = 1.5pF, L1 = 4.7nH, L2 = 3.3nH, L3 in the circuit of FIG. = 2.0nH, L4 = 1.2nH, L5 = 2.7nH, L6 = 3nH, L7 = 2.7nH, L8 = 3.9nH to implement the triplexer.

In this case, the three bands are transmitted through a radio frequency (RF) processing unit (tripler), each of the 25 MHz band for transmission and reception in the CDMA band, the 60 MHz band for transmission and reception in the US PCS band, and the center (1575.42 MHz) band of the GPS. The frequency band is divided into 1 MHz bands for transmission and reception.

These triplexer circuits can achieve better isolation and insertion loss by using series and parallel tuning circuits.

In particular, the GPS band compensates for the insertion loss of the US PCS band, which is a high frequency band using the inductor (L5), and has a built-in Saw filter. Therefore, an optimal value of 1575.42MHz is applied to the MMIC and the discrete circuit.

In FIG. 1, the concept of triplexer resonance may be expressed as Equation 1 below.

Q = relative bandwidth of through response

f ₀ = center frequency of diplexer (Hz)

BW _3dB = 3-dB bandwidth of desired though response (Hz)

Hereinafter, the operation of the triplexer implementing the circuit of FIG. 1 will be described in more detail with reference to FIGS. 2 to 4.

2 to 4 are graphs showing the results of experiments of the characteristics of the triplexer circuit according to the present invention, and FIG. 2 is an insertion loss, return loss, and attenuation characteristic for each frequency band. This is a graph.

Referring to the graph of FIG. 2, the insertion loss of the CDMA bands (m8, m9) in the triplex circuit of the present invention is -0.8 to -0.5 (dB), which is not significantly different from other diplexers. Insertion loss in GPS band (m4) with GPS Saw filter is -0.756 (dB), ensuring maximum performance by saw filter, and insertion loss in US PCS band (m1). 1.526 dB, slightly higher than other bands, but very good, and return loss in the low and high frequency bands (m2, m3, m5, m6, m7, m10, m11, m12) with margins well above 15 dB. Again, we can see that we have enough margin in all frequency bands.

3 is a graph showing the separation characteristics when viewing different bands in CDMA, GPS, and US PCS. As shown therein, 882.0 MHz (m15, m20, m21), 1.575 GHz (m13, m18, m19), In the 1.960 GHz (m14, m16, m17) bands, the separation (S (2,3), S (2,4), S (4,3)) is achieved with good margins of at least 15 dB. Able to know. That is, it can be seen through the graph that the separation characteristics of the circuit according to the present invention are good.

For reference, in RF, impedance is always considered. Impedance “Z” is a word opposite to current, and can be referred to as a two-dimensional vector composed of resistance and reactance. Here, the resistance (R) represents the degree of disturbing the flow of the current, the reactance (X) represents the capacitance and the inductance energy, which can be said to be a unit of measurement of the amount of energy is accumulated and consumed.

Impedance can be expressed using Cartesian coordinates with the resistance section as the X axis and the inductive and capacitive sections as the Y axis in the low frequency band. The change is so great that from this point on we will use the Smith Chart. Therefore, the output impedance characteristic in each frequency band m13, m14, m15 according to the present invention can be seen through the Smith chart shown in FIG.

As described above, the triplexer circuit of the tri-mode terminal of the present invention combines several passive elements without using a single filter in a tri-mode terminal that simultaneously processes various modes such as CDMA, GPS, and US-PCS. Therefore, by improving insertion loss and separation characteristics, there is an effect of effectively separating signals between frequency bands.

In addition, the present invention implements a circuit incorporating a GPS saw filter using a passive element as a discrete circuit, so that it can be manufactured at a low cost and the terminal can be designed by optimizing the space utilization of a circuit board (PCB). In addition, the implementation of the MMIC by the proposed circuit is also possible.

In addition, the conventional triplexer by SPDT and SP3T has the disadvantage of being vulnerable to static electricity, but the present invention can be eliminated the problem caused by static electricity by implementing a passive element, desired by the series resonance and parallel resonance By implementing the effect of selecting only frequency, it is possible to further improve the separation characteristics of CDMA, US PCS and GPS bands.

Claims (7)

A triplexer circuit for dividing a signal received through an antenna into three frequency bands (first, second, and third frequency bands), A first resonator unit having one end connected to an antenna and rejecting a frequency band signal other than the first frequency band; A second resonator connected to the other end of the first resonator to pass only a first frequency band signal; Third and fifth resonators connected to the antenna in parallel with the first resonator to reject signals other than a second frequency band; Fourth and sixth resonator parts connected to the third and fifth resonator parts and the other end of the fifth resonator part, respectively, and allow only a second frequency band signal to pass therethrough; And a third frequency band signal separated by an inductor connected to the antenna in parallel with the third resonator and a filter connected in series with the other end of the inductor. The tri-mode terminal as claimed in claim 1, wherein the first resonator is configured to band-reject a band signal other than the first frequency band by connecting the capacitor C2 and the inductor L2 in parallel. Triplexer circuit. 2. The second resonator of claim 1, wherein the second resonator comprises a inductor having one end connected to an output end of the first resonator, a capacitor connected to the other end of the inductor, and an inductor connected to the other end of the capacitor and grounded at the other end thereof. Triplexer circuit of the tri-mode terminal, characterized in that configured to select the band. The triple of the tri-mode terminal of claim 1, wherein the third and fifth resonators are configured to band reject a band signal other than the second frequency band by a capacitor and an inductor connected in parallel. Lexer circuit. The method of claim 1, wherein the fourth resonator is configured to pass the second frequency band signal by the capacitor C3 and the inductor L3 having one end connected to the output terminal of the third resonator and the other end grounded. The triplexer circuit of the tri-mode terminal. The method of claim 1, wherein the sixth resonator has one end connected to an output terminal of the fifth resonator, a second end connected to the other end of the capacitor, and one end connected to an output terminal of the fifth resonator and the other end grounded. And the other end of which is configured to pass the second frequency band signal by a grounded capacitor. The triplexer circuit of claim 1, wherein the filter is a SAW filter.

Images