This application claims priority from Korean Patent Application No. 10-2010-0043609, filed on May 10, 2010, the disclosure of which is incorporated herein in its entirety by reference.
1. Field
Apparatuses consistent with exemplary embodiments relate to a transceiver, and more particularly to, a transceiver for transmitting operating power to an object transceiver such as a radio frequency identification (RFID) tag in a receiving mode.
2. Description of the Related Art
Referring to
Each of the transceivers 111a through 111m must use a spurious wave removing filter for removing a spurious wave of a transmission signal from a transmitting unit according to a spurious wave specification so as to minimize an influence on an adjacent channel. Thus, the spurious wave removing filter has a very narrow transmission frequency band.
Referring to
An oscillation signal generated from an oscillation unit also has a phase noise component. The oscillation signal leaks from a signal division element or is reflected from a transmission and reception antenna, and is received along with a reception signal. Thus, if a leak component of the oscillation signal including a changed phase noise component is down-converted, the reception signal has a very large phase noise.
For example, if a transmission frequency band is between 950 MHz and 952 MHz, the delay time extracted by applying measured data to a calculation equation is about 300 nS. Such a delay time is very long compared to the overall delay time of all devices, except for the spurious wave removing filter, and response delay time between tags and readers. Further, as is well known, each of the RFID readers as transceivers 111a through 111m transmits a tag power signal to each of the RFID tags as object transceivers 121a through 121n and 191a through 191n in a receiving mode. The tag power signal partially leaks from the signal division element or is reflected from the transmission and reception antenna and is received along with the reception signal.
Therefore, the reception signal that is down-converted to the base frequency band includes phase noise and leakage and reflection signals, which deteriorates receiving performance of each of the transceivers 111a through 111m.
In conclusion, an increase in the delay time due to the spurious wave removing filter causes a phase noise component in the down-converted reception signal, which reduces a recognizable distance or anti-collision performance.
One or more exemplary embodiments provide a transceiver that may effectively remove a phase noise component remaining in a down-converted reception signal, thereby increasing a recognizable distance or improving anti-collision performance.
According to an aspect of an exemplary embodiment, there is provided a transceiver including an oscillation portion, a transmission portion, a spurious wave removing filter, a transmission and reception antenna, a signal division element, an extraction signal adjusting portion, and a receiving portion.
The oscillation portion may generate an oscillation signal.
The transmission portion may convert a transmission signal of a base frequency band into a transmission signal of a radio frequency band by using the oscillation signal generated by the oscillation portion.
The spurious wave removing filter may remove a spurious wave of the transmission signal converted by the transmission portion.
The signal division element may apply the transmission signal of the radio frequency band, which is processed by the spurious wave removing filter to the transmission and reception antenna, and receives a reception signal of the radio frequency band from the transmission and reception antenna.
The extraction signal adjusting portion may extract the transmission signal from the signal division element and adjust a phase of the extracted signal to generate an output signal.
The receiving portion may convert the reception signal received at the signal division element into a reception signal of the base frequency band by using the output signal from the extraction signal adjusting portion.
According to the transceiver of the present exemplary embodiment, a long delay time of the spurious wave removing filter causes a change of the phase noise component in the oscillation signal generated from the oscillation unit.
However, while the receiving portion converts the reception signal of the radio frequency band into the reception signal of the base frequency band, the output signal adjusted by the extraction signal adjusting portion is combined with the reception signal of the radio frequency band, and thus, the phase noise component may be removed from the reception signal of the radio frequency band.
That is because the output signal adjusted by the extraction signal adjusting portion is the transmission signal extracted from the signal division element so that the phase noise component of the output signal overlaps that of the reception signal of the radio frequency band.
However, when the transmission signal extracted from the signal division element is merely used for down-conversion of a frequency, a direct current (DC) noise occurs in the reception signal of the base frequency band. Such a DC noise component has a uniform frequency band like the phase noise component, which influences the reception signal down-converted to the base frequency band.
Thus, the extraction signal adjusting portion extracts the transmission signal from the signal division element, and adjusts a phase of the extracted signal, thereby preventing the phase noise from being influenced and the DC noise from occurring.
In conclusion, according to the transceiver of the present exemplary embodiment, a phase noise component may be effectively removed from a reception signal, thereby increasing a recognizable distance and improving anti-collision performance.
The above and other aspects will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, in which:
Hereinafter, the exemplary embodiments will be described more fully with reference to the accompanying drawings. The detailed description and the drawings are introduced to provide an understanding of the inventive concept and the detailed descriptions of well-known technologies may be omitted. In addition, the specification and the drawing are not provided to limit the scope of the inventive concept and the scope of the inventive concept is defined by the claims. The terminologies used herein are for the purpose of describing exemplary embodiments, and thus, may be interpreted to correspond to the meaning and concept of the inventive concept.
Referring to
The oscillation portion 301 and 302 generates an oscillation signal A3.
The transmission portion 303 through 305 converts a transmission signal B3 of a base frequency band into a transmission signal C3 of a radio frequency band.
The spurious wave removing filter 306 may remove a spurious wave from the transmission signal C3 of the radio frequency band.
The signal division element 307 applies a transmission signal of the radio frequency band, which is processed by the spurious wave removing filter 306 to the transmission and reception antenna 314, and receives a reception signal of a radio frequency band from the transmission and reception antenna 314.
The extraction signal adjusting portion 309 through 311 extracts the transmission signal from the signal division element 307, and adjusts a phase of the extracted signal. Further, the extraction signal adjusting portion 309 through 311 adjusts a size and a delay time of the extracted signal.
The receiving portion 308, 312, and 313 converts a reception signal received by the signal division element 307 into a reception signal F3 of a base frequency band by using an output signal D3 adjusted by the extraction signal adjusting portion 309 through 311.
According to the RFID reader as a transceiver of the present exemplary embodiment, a long delay time of the spurious wave removing filter 306 causes a change of a phase noise component in the oscillation signal A3 generated from the oscillation unit 301 and 302.
However, while the receiving portion 308, 312, and 313 converts the reception signal into the reception signal F3 of the base frequency band, the output signal D3 adjusted by the extraction signal adjusting portion 309 through 311 is combined with a reception signal E3, and thus, the phase noise component may be removed from the reception signal.
That is, because the output signal D3 adjusted by the extraction signal adjusting portion 309 through 311 is the transmission signal extracted from the signal division element 307, the phase noise component of the output signal D3 overlaps that of the reception signal E3.
However, when the transmission signal extracted from the signal division element 307 is merely used for down-conversion of a frequency, a direct current (DC) noise occurs in the reception signal F3 of the base frequency band. Thus, it may be possible to prevent the DC noise from occurring by adjusting the phase of an extracted signal in the extraction signal adjusting portion 309 through 311.
In conclusion, according to the RFID reader as a transceiver of the present exemplary embodiment, a phase noise component may be effectively removed from a reception signal, thereby increasing a recognizable distance and improving anti-collision performance.
The RFID reader as a transceiver of the present exemplary embodiment will now be described in more detail.
The oscillation portion 301 and 302 is respectively a phase locked loop (PLL) circuit 301 and a signal generating unit 302. The signal generating unit 302 generates an oscillation signal A3 of a set frequency. The PLL circuit 301 is connected to the signal generating unit 302 and fixes a frequency of the oscillation signal A3.
If an amplitude of the oscillation signal A3 is not considered, the oscillation signal A3 may be defined according to equation 1 below,
A
3=cos [ωCt+Φ(t)], [Equation 1]
where ωC denotes an oscillation angular frequency, and Φ(t) denotes a phase noise component of the oscillation portion 301 and 302.
The transmission portion 303 through 305 is respectively a digital transmission unit 303, an up mixer 304, and an analog transmission unit 305.
The digital transmission unit 303 encodes transmission data, converts the encoded transmission data into an analog signal, and generates a transmission signal B3 of a base frequency band.
The transmission signal B3 of the base frequency band has a DC voltage in a receiving mode. Thus, if an amplitude of the transmission signal B3 is not considered, the transmission signal B3 of the base frequency band may be defined according to equation 2 below.
B
3=cos 0°=1 [Equation 2]
The up mixer 304 converts the transmission signal B3 of the base frequency band into the transmission signal C3 of the radio frequency band by using the oscillation signal A3 generated by the oscillation portion 301 and 302.
Thus, if an amplitude of the transmission signal C3 is not considered, since the transmission signal C3 of the radio frequency band is obtained by multiplying a function of the transmission signal B3 of the base frequency band and a function of the oscillation signal A3, the transmission signal C3 of the radio frequency band may be defined according to equation 3 below.
B
3=cos [ωCt+Φ(t)], [Equation 3]
where ωC denotes an oscillation angular frequency, and Φ(t) denotes the phase noise component of the oscillation portion 301 and 302.
The analog transmission unit 305 amplifies the transmission signal C3 converted by the up mixer 304, and inputs the amplified transmission signal C3 into the spurious wave removing filter 306.
A surface acoustic wave (SAW) filter may be used as the spurious wave removing filter 306.
A directional combiner, a Wilkinson power divider, an unequal Wilkinson power divider, a rat-race power divider, and the like may be used as the signal division element 307.
The extraction signal adjusting portion 309 through 311 is respectively a delay unit 309, an attenuation unit 310, and a phase adjusting unit 311 for performing a main function. The locations of the phase adjusting unit 311, the delay unit 309, and the attenuation unit 310 as shown in
The delay unit 309 delays a signal extracted from the signal division element 307 by a set period of time, and inputs the delayed signal into the attenuation unit 310 to remove the phase noise.
A distribution element, such as a microstrip line structure, a strip line structure, and a coaxial cable, or a filter, an inductor, and a capacitor may be used as the delay unit 309. In this regard, a lumped element or a distribution element, or an electrically adjustable element, such as a varactor diode and a transistor, may be used as the capacitor. Likewise, the lumped element or the distribution element may be used as the inductor.
The attenuation unit 310 reduces an amplitude of the extracted signal for an operation of a rear end.
When the attenuation unit 310 is manufactured as a fixing attenuation unit, a lumped element or a distribution element may be used as the fixing attenuation unit. When the attenuation unit 310 is manufactured as a variable attenuation unit, an electrically adjustable element, such as a PIN diode, the lumped element, or the distribution element may be used as the variable attenuation unit.
The phase adjusting unit 311 adjusts a phase of the extracted signal processed by the attenuation unit 310 to generate the output signal D3.
When the phase adjusting unit 311 is manufactured as a fixing phase adjusting unit, a lumped element or a distribution element may be used as the fixing phase adjusting unit. When the phase adjusting unit 311 is manufactured as a variable phase adjusting unit, an electrically adjustable element, such as a varactor diode, the lumped element, or the distribution element may be used as the variable phase adjusting unit.
If an amplitude of the output signal D3 is not considered, the output signal D3 of the phase adjusting unit 311 may be defined according to equation 4 below,
D
3=cos [ωC(t−tRO)+Φ(t−tRO)+θ], [Equation 4]
where θ denotes a phase adjusted by the phase adjusting unit 311, tR0 denotes a total delay time of the output signal D3, and ωC denotes an oscillation angular frequency.
The receiving portion 308, 312, and 313 is respectively an analog receiving unit 308, a down mixer 312, and a digital receiving unit 313.
The analog receiving unit 308 amplifies the reception signal received from the signal division element 307, and may remove a harmonic wave component from the amplified signal to generate the reception signal E3.
If an amplitude of the reception signal E3 is not considered, the reception signal E3 processed by the analog receiving unit 308 may be defined according to equation 5 below,
E
3=cos [ωC(t−tRO)+Φ(t−tRO)]+cos [(ωC+ωm)(t−tRO−tT)+Φ(t−tRO−tT)], [Equation 5]
where ωC denotes an angular oscillation frequency, tR0 denotes a delay time of the RFID reader mainly caused by a spurious wave removing filter, ωm denotes an angular frequency of a base frequency band included in a reception signal from a tag, and tT denotes a response delay time in proportion to a distance between the tag and the RFID reader.
Thus, Φ(t−tRO) denotes a phase noise component caused by a delay of the extracted signal, and Φ(t−tRO−tT) denotes a phase noise component caused by a delay of the reception signal applied to the down mixer 312.
The down mixer 312 converts the reception signal E3 of the analog receiving unit 308 into the reception signal F3 of the base frequency band by using the output signal D3 of the phase adjusting unit 311.
Thus, if the phase θ adjusted by the phase adjusting unit 311 is 90° without considering an amplitude of the reception signal F3, since the reception signal F3 of the base frequency band is obtained by multiplying a function of the output signal D3 adjusted by the extraction signal adjusting portion 309 through 311 and a function of the reception signal E3 of the analog receiving unit 308, the reception signal F3 may be defined according to equation 6 below.
F
3=cos [ωm(t−tRO)+ωCtT−θ], [Equation 6]
where ωm denotes an angular frequency of a base frequency band included in the reception signal from a tag, tRO denotes a total delay time of the output signal D3, ωC denotes an oscillation angular frequency, and tT denotes a response delay time in proportion to a distance between the tag and the RFID reader.
Thus, in comparison of Equations 5 and 6, a DC noise component as well as the phase noise component may be removed from the reception signal F3 of the base frequency band. In Equation 6, since ωCtT and θ denote phases, ωCtT and θ do not act as phase noises.
Like reference numerals denote like elements between
Referring to
A control unit 41 controls the attenuation unit 310, the phase adjusting unit 311, and the delay unit 309 according to the noise data generated by the digital receiving unit 313.
Like reference numerals denote like elements between
Referring to
The noise detection filter 51 detects a noise component of the reception signal F3 of the down mixer 312.
A low pass filter (LPF), a high pass filter (HPF), a band rejection filter (BRF), and a band pass filter (BPF), and the like may be used as the noise detection filter 51.
The analog-digital conversion unit 52 converts the noise component detected by the noise detection filter 51 into digital data and generates noise data.
The control unit 53 controls the attenuation unit 310, the phase adjusting unit 311, and the delay unit 309 according to the noise data generated by the analog-digital conversion unit 52.
As described above, according to the transceiver of the present exemplary embodiments, the spurious wave removing filter 306 causes a change of the phase noise component in the oscillation signal A3 generated from the oscillation unit 301 and 302.
However, while the receiving portion 308, 312, and 313 convert the reception signal into the reception signal F3 of the base frequency band, the output signal D3 adjusted by the extraction signal adjusting portion 309 through 311 is combined with a reception signal E3, and thus the phase noise component may be removed from the reception signal.
This is because the output signal D3 adjusted by the extraction signal adjusting portion 309 through 311 is the transmission signal extracted from the signal division element 307, so that the phase noise component of the output signal D3 overlaps that of the reception signal E3.
However, when the transmission signal extracted from the signal division element 307 is merely used for down-conversion of a frequency, a DC noise occurs in the reception signal F3 of the base frequency band. Such DC noise has a frequency band like the phase noise component, which influences a reception signal down-converted to a base frequency band.
Thus, the extraction signal adjusting portion 309 through 311 extracts the transmission signal of the signal division element 307, and adjusts a phase of the extracted signal, thereby preventing the phase noise from being influenced and the DC noise from occurring.
In conclusion, according to the transceiver of the present exemplary embodiment, a phase noise component may be effectively removed from a reception signal, thereby increasing a recognizable distance and improving the anti-collision performance.
While the exemplary embodiments have been particularly shown and described, it will be understood by one of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the inventive concept as defined by the following claims. The exemplary embodiments should be considered in a descriptive sense only and not for purposes of limitation. Therefore, the scope of the inventive concept is defined not by the detailed description of the exemplary embodiments but by the following claims, and all differences within the scope will be construed as being included in inventive concept.
Number | Date | Country | Kind |
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10-2010-0043609 | May 2010 | KR | national |