Abstract:
A frequency synthesizer of a transceiver for generating a crystal oscillation frequency and a carry frequency having been done a process of frequency offset cancellation with that of another transceiver. The frequency offset cancellation of the frequency synthesizer is done in accordance with a wireless signal which is transmitted from another transceiver received. The frequency synthesizer has a first sigma-delta modulator receiving a signal transmitted by a transceiver at far area responding thereafter a frequency divisor value in accordance with the channel information of the received signal and a frequency offset between two.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention pertains to a frequency synthesizer, particularly to a frequency synthesizer of a first transceiver at local generating a crystal oscillation signal and a carrier signal whose frequencies have been calibrated by tracing a BPSK modulated signal received, which is transmitted from a second transceiver at a distant location. 
       BACKGROUND OF THE INVENTION 
       [0002]    With the development of wireless communication, positioning technique can be widely applied on many fields and provide potential business market opportunities thus it is always a hot topic. For instance, in the global satellite position, back car radar, directional car search, people searching, or object searching are particularly useful for the team tours in mountain if the object tied with or team member to be searched bring a transceiver. One of positioning techniques may refer the RSSI (received signal strength indicator) to derive the distance of the object or people. The RSSI position technique involves using the RFID and antennas. To position an object in a positioning space, four antennas are demanded or in a 2D plane by three antennas.  FIG. 1A  depicts a planar position schematic diagram. Three antenna readers are assumed placed at position A, B, C and a target to be positioned is assumed at the point P. If the target has a transmitter to transmit a wireless signal then the antenna readers A, B, and C would receive the signal thereby the distances d p   A , d p   B , d p   C ; can be estimated according to the RSSI values detected. Accordingly, the coordinate of the P can be obtained by solving the coupling equations: 
         [0000]        d   p   A =√{square root over (( x   A   −x   P ) 2 +( y   A   −y   P ) 2 )}{square root over (( x   A   −x   P ) 2 +( y   A   −y   P ) 2 )}  (1)
 
         [0000]        d   p   B =√{square root over (( x   B   −x   P ) 2 +( y   B   −y   P ) 2 )}{square root over (( x   B   −x   P ) 2 +( y   B   −y   P ) 2 )}  (2)
 
         [0000]        d   p   C =√{square root over (( x   C   −x   P ) 2 +( y   C   −y   P ) 2 )}{square root over (( x   C   −x   P ) 2 +( y   C   −y   P ) 2 )}  (3)
 
         [0003]    However, the RSSI values are vulnerable to affect by environmental factors unless the RSSI values have be passed a long training time and/or correctness thereafter. 
         [0004]    Another position method of the radio signal positioning is by time arriving, which is found to be more precisely and less affected by environment than RSSI. Please refer to  FIG. 1B , a first signal is sent out at position A by a first transceiver, which cost a duration t dur . Upon receiving the first signal by the second transceiver at time t B  at the position B, the second transceiver transmits a second signal back immediately and received by the first transceiver at time t A . 
         [0005]    The distance d AB , between position A and position B can be expressed as: 
         [0000]    
       
         
           
             
               d 
               AB 
             
             = 
             
               
                 
                   
                     t 
                     A 
                   
                   - 
                   
                     t 
                     B 
                   
                 
                 2 
               
               × 
               C 
             
           
         
       
       
         
           
             where 
              
             
                 
             
              
             C 
              
             
                 
             
              
             is 
              
             
                 
             
              
             the 
              
             
                 
             
              
             velocity 
              
             
                 
             
              
             of 
              
             
                 
             
              
             
               light 
               . 
             
           
         
       
     
         [0006]    In practice, both of the wireless signals are modulated signals transmitted according to a data packet protocol, which are a baseband signal modulated by a carrier signal. After the modulated signal received by the transceiver, the modulated signal are demodulated to return to the baseband signals. To position by using wireless signal technique, the crystal oscillation frequencies of the first transceiver and the second transceiver should be in consistence; otherwise, the arrival time would be incorrect. 
         [0007]    Unfortunately, even using the most advance semiconductor processes, two crystal oscillators are generally found to have a frequency offset. The frequency offset is usually negligible, e.g. one or several ppm. (parts per million). However, the distance error derived by duration multiply the velocity of light caused by the frequency offset will be not negligible but significantly. Thus if there is any frequency offset, it will be inferior to use in positioning. 
         [0008]    Consequently, it is important to know the frequency offset between two oscillation frequencies and further cancel them before using them in frequency synthesizer to generate a carrier signal. 
         [0009]    A conventional but exemplary frequency synthesizer is disclosed by an U.S. Pat. No. 7,649,428 having a title “Method and System for Generating Noise in a Frequency Synthesizer.” The patent is to generate a noise portion of an input signal within the frequency synthesizer and appending the noise portion the noise portion to a control portion of the input signal. The functional blocks diagram, please see the  FIG. 1C . The frequency synthesizer is a fractional-N synthesizer with a PLL (phase locked loop)  20 , a sigma delta modulator  32 , and a mixer  34 . The phase locked loop  20  includes a phase frequency detector (PFD)  22 , a charge pump  24 , a loop filter  26 , a voltage-controlled oscillator  28 , a multi-modulus divider  30  in series connected to compose a loop. The output signal Fout of the VCO  28  is fed back to the multi-modulus divider  30  and the latter then outputs a signal and is compared with an input signal FIN by the phase detector  22 . 
         [0010]    The sigma-delta modulator  32  outputs a fractional part Δ[K], which is then summed with an integer N by a summer  34 . Accordingly, the summer  34  provides a fractional integer, represented by “N.Δ[K]” as a divisor to the multi-modulus divider  30 . As a result, the frequency Ferr is equal to Fout divided by (N.Δ[K]) 
         [0011]    The frequency Ferr is then compared with the FIN of the input signal of the PLL circuit  20 . If the phase difference between two input signals Ferr, FIN of the PFD  22  is over ±2π then the PFD  22  is operated in the frequency detect mode, then the charge pump  24  operated is in full speed, i.e., running a constant current. The loop filter  26  integrates this current and the result is continuously charging control voltage applied to the VCO  28  till the phase difference between two input signal drops below 2π. 
         [0012]    The PFD is thus run into phase detect mode. The output of the charge pump  24  is proportional to the phase difference. Once the phase difference of two signals reaches zero. The device enters into the phase locked state. 
         [0013]    The prior art doesn&#39;t relate to a method of correcting the frequency offset between two transceivers at two locations. 
         [0014]    An object of the present invention thus provides a frequency synthesizer having frequencies outputted tracing the signal received so that the frequency offset of two frequency synthesizers of the transceivers can be cancelled. 
       SUMMARY OF THE INVENTION 
       [0015]    The present invention discloses a frequency synthesizer of a transceiver for generating a crystal oscillation frequency and a carry frequency having frequency offset cancellation with that of another transceiver. 
         [0016]    The frequency synthesizer comprises a phase frequency detector, a charge pump, a loop filter, a voltage-controlled oscillator (VCO), a first multi-modulus divider, and a first sigma-data (Σ-Δ) modulator connected to compose a phase locked loop. In addition to the phase locked loop (PLL), the frequency synthesizer further comprises a second multi-modulus divider, a second Σ-Δ modulator; and a frequency offset estimation unit. 
         [0017]    The frequency offset estimation unit provides the information of the frequency offset between the two frequency synthesizers 
         [0018]    The first Σ-Δ modulator generates a divisor according to the channel information of the first signal received according to a look-up table and further provides a calibrated divisor for the first multi-modulus divider according to the data about frequency offset. 
         [0019]    After the PLL entered the phase locked state, the frequency synthesizer outputs a calibrated frequency for a carrier signal. The second Σ-Δ modulator provides a divisor to the second multi-modulus divider in accordance with the channel information of the first signal received. The second multi-modulus divider then generates a calibrated crystal oscillation frequency by using the calibrated carrier frequency outputted from the VCO as dividend divided the divisor. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0020]    The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same becomes better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein: 
           [0021]      FIG. 1A  shows three antenna to position a target in accordance with the prior art. 
           [0022]      FIG. 1B  shows a positioning method using time arrived in accordance with the prior art. 
           [0023]      FIG. 1C  shows a block diagram of a frequency synthesizer in accordance with the prior art. 
           [0024]      FIG. 2  shows a function block diagram of a frequency synthesizer in accordance with the present invention. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0025]    As mentioned above, if a crystal oscillators of a transceiver does not the same frequency as the other&#39;s, i.e. exists a frequency offset, then, it will result in positioning errors, and the errors is increased with the frequency deviation. 
         [0026]    The reason is obvious because once the frequency synthesizers use such crystal oscillators to generate UHF (UHV) carrier signals, the frequency inconsistent will be further amplified by them. 
         [0027]    The present invention is to solve forgoing problems. The frequency synthesizer generates a calibrated crystal oscillation frequency and a calibrated carrier frequency. Described hereinafter the “calibrated” means the carry frequency of the local transceiver based on the crystal oscillation frequency, which has traced the wireless signal received. That is, frequency offset between two transceivers has been cancelled. 
         [0028]    In other words, the local frequency synthesizer of the local transceiver will refer the signals received from the distant transceiver so that the crystal frequencies of two transceivers are in consistence. 
         [0029]    Please refer to  FIG. 2 , the frequency synthesizer  200  comprises a phase frequency detector  222 , a charge pump  224 , a loop filter  226 , a voltage-controlled oscillator  228 , a first multi-modulus divider  230   a , a second multi-modulus divider  230   b , a first sigma delta (Σ-Δ) modulator  232   a  and a second Σ-Δ modulator  234   a . The frequency synthesizer  200  may also be read as a phase locked loop with a calibrated divisor provided by the first Σ-Δ modulator  232   a , which receives a first signal; the circuit further comprise the second multi-modulus divider  230   b , and the second sigma delta modulator  234   a . The latter two will not be operated until the PLL circuit has been run in the frequency locked state. The frequency synthesizer  200  outputs a calibrated crystal oscillation frequency FOUT 2 ′=Xal′. The apostrophe append on the Xal is to represent the frequency is not an original frequency of a crystal oscillator but includes a calibrated factor already. 
         [0030]    In  FIG. 2 , the phase frequency detector  222  has a first input terminal IN 0  to receive a signal FIN, which is the original crystal oscillation frequency Xal at the local and the second input terminal is fed by an output signal of the first multi-modulus divider  230   a . The phase frequency detector  222  compares the two then outputs accordingly a signal to the charger pump  224 . The charger pump  224  then outputs a signal to the loop filter  226  and then the latter  226  outputs a resulted voltage to the voltage-controlled oscillator (VCO)  228 . The oscillation frequency FOUT 1  outputted from the output terminal OUT 1  is further fed back to the first multi-modulus divider  230   a  and the second multi-modulus divider  230   b.    
         [0031]    The first Σ-Δ modulator  232   a  has a first look-up table  234   a , which is a hardware providing a relationship between channel information or called channel number CH# versus predetermined divisor. The first Σ-Δ modulator  232   a  has two input terminals IN 1 , IN 2 . The input terminal IN 1  receives a radio frequency and accordingly picks up the channel information CH#. The input terminal IN 2  receives a frequency offset k in a unit of ppm. from a offset estimation unit  240 . Accordingly, the look-up table  234   a  generates a divisor D. 
         [0032]    The divisor D may be just an integer I only or an integer with a fractional “I.f”. For example, the look-up table  234   a  may output a divisor of 153 if a radio frequency received is transmitted through a channel number 21 or of 153.5 if it is through a channel number 20 according to the look-up table  234   a.    
         [0033]    The second input terminal IN 2  of the first Σ-Δ modulator  232   a  is provided for receiving an offset expressed by k ppm. The offset will reflect on the divisor D. For example, the offset is of 1 ppm and the divisor is of 153 then the output of the first Σ-Δ modulator  232   a  will be D′=153.000153, where D′=D (1+k ppm). 
         [0034]    Similarly, if the signal transmitted is through CH number 21 then the divisor is 153.5. 1 ppm of 153.5 will make “D′=153.000153”. The first Σ-Δ modulator  232   a  will demand a higher resolution in the output than the second Σ-Δ modulator  232   b  since aside from the first look-up table, it depends on the offset too. 
         [0035]    The offset value is provided by offset estimated unit  240 , which derives an offset value in accordance with the I_DATA (in-phase signal) and Q_DATA (quad signal) received by terminal IN 3  and IN 4 . The detailed description is disclosed in patent application NO. 0981334853 of Taiwan. 
         [0036]    The first Σ-Δ modulator  232   a  outputs the a divisor D′ to the first multi-modulus divider  230   a . Accordingly, the output of the first multi-modulus divider  230   a  is the signal frequency FOUT 1 ′ divided by the divisor D′. The frequency represented by the quotient is then compared with the signal FIN. When the phase difference between two signals is over ±2π, the phase frequency detector  222  is operated in a detected mode and the charge pump  224  runs at full speed until the phase difference within 2π, where the phase frequency detector  222  is operated in a phase detection mode. The voltage output of the charge pump  224  is proportional to the phase difference. Once the difference reaches zero, the PLL into a phase locked state. Thereafter, the second multi-modulus divider  230   b  and the second Σ-Δ modulator  232   b  start to work. 
         [0037]    Firstly, the second Σ-Δ modulator  232   b  with its input terminal IN 1  receives the first signal. Consequently, the second look-up table  232   b  of the second Σ-Δ modulator  232   b  outputs a divisor D=153 for the channel information of the first signal is CH number of 20 and for a frequency outputted by an original crystal oscillator is 16 MHZ and a frequency outputted by the VCO  228  upon in the phase locked state is thus 
         [0000]      16 MHz×153.000153=2448.002448 MHz (1 ppm frequency offset gives the same variation 1 ppm at the output terminal.
 
         [0038]    The frequency 2448.002448 MHz divided by the divisor D=153 will get quotient FOUT 2 =16.000016 MHz, the same variation too. The hardware of the second Σ-Δ modulator  232   b  is simpler than first Σ-Δ modulator  232   a  since it does not involve the offset issue. 
         [0039]    The benefits of the present invention are: 
         [0040]    The crystal oscillation frequency and carrier frequency outputted by the frequency synthesizers at the local and the distant according to the present invention are calibrated and thus is in consistence. The positioning precision reaches 1 ppm level thus the transceiver will give accurate and reliable results if it has the forgoing frequency synthesizer. 
         [0041]    As is understood by a person skilled in the art, the foregoing preferred embodiment of the present o invention is an illustration of the present invention rather than limiting thereon. It is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims, the scope of which should be accorded the broadest interpretation so as to encompass all such modifications and similar structure.