KR101130882B1 - Polar transmitter for compensating time-delay, operation method thereof and portable device including the same - Google Patents

Abstract

PURPOSE: A polar transmitter with a time delay compensation function and an operating method thereof, and a mobile terminal with the same are provided to prevent a time delay when signals are transmitted/received. CONSTITUTION: A baseband signal processing unit(210) outputs a pulse modulation signal for detecting a time delay. An amplitude modulating unit(220) generates an amplitude modulating signal by the pulse modulation signal. A phase modulating unit(230) generates a phase modulating signal by the pulse modulation signal. A time delay compensating unit(250) differentially amplifies the difference between an output of the amplitude modulating unit and an output of the phase modulating unit.

Description

A polar transmitter having a time delay compensation function, a method of operating the same, and a portable terminal including the same {Polar Transmitter For Compensating Time-Delay, Operation Method Such and Portable Device including the same}

The present invention relates to a transmitter, and more particularly, to a polar transmitter for performing time delay compensation, a method of operating the same, and a portable terminal including the same. This invention is derived from a study conducted as part of the IT source technology development project of the Ministry of Knowledge Economy. [Task control number: K1001869, Assignment name: Research on environment adaptive autonomous control technology of mobile communication wireless access method]

Recently, researches on terminals operating in multi-band and multi-mode like smart terminals have been actively conducted. In order to implement a terminal operating in a multi-band, multi-mode, the configuration of the terminal should be simple. In addition, in terms of transmitters, efficiency, linearity, and wideband operation must be ensured in order to implement a terminal transmitter operating in a multiband or multimode mode.

On the other hand, a polar transmitter is recognized as a transmitter capable of operating in a wide frequency range because it is easy to integrate due to its simple configuration and only a few devices need to be widened due to its simple configuration. Therefore, a lot of research on the polar transmitter has recently been conducted. Since the polar transmitter does not require an analog modulator, a local oscillator, a channel filter, or the like, the structure is simple and easy to integrate. In addition, the polar transmitter may use a high efficiency nonlinear power amplifier by dividing the original signal into a magnitude modulation signal and a phase modulation signal and combining the processed signals in a power amplifier. That is, the magnitude modulated signal generated by the polar transmitter is easy to implement because of low frequency, and the phase modulated signal is is enveloped so that it can be amplified using a nonlinear power amplifier. By combining the original signal amplified can be obtained. However, if the time delays of the magnitude modulation path and the phase modulation path are not the same, the combined signal from the power amplifier has a problem in that a distorted signal different from the original signal is output.

Accordingly, an object of the present invention is to provide a polar transmitter capable of performing time delay compensation using a simple hardware and algorithm, a method of operating the same, and a portable terminal including the same.

A polar transmitter capable of performing time delay compensation according to a preferred embodiment of the present invention for achieving the above object is a baseband signal processor for outputting a pulse modulated signal for detecting the occurrence of a time delay, the pulse modulated signal A magnitude modulation unit for generating and outputting a magnitude modulation signal from the phase modulation unit, a phase modulation unit for generating and outputting a phase modulation signal from the pulse modulation signal, and comparing the output of the magnitude modulation unit with the output of the phase modulation unit and differentially amplifying the difference And a time delay compensator configured to transfer the baseband signal processor to the baseband signal processor, wherein the baseband signal processor detects a time delay occurrence according to the type of the differentially amplified signal, and determines whether the time delay occurs. And at least one time error of the signal transmitted to the phase modulator. And adjusting the preset.

A method of operating a polar transmitter capable of performing time delay compensation according to a preferred embodiment of the present invention for achieving the above object is a process of generating a pulse modulated signal for checking the time delay generation, the pulse modulated signal Generating a phase modulated signal from the magnitude modulated signal and the pulse modulated signal, initializing a time offset of the signal transmitted to the magnitude modulator, and a time offset of the signal transmitted to the phase modulator, the magnitude modulated signal and the Comparing phase modulated signals and checking the difference, and detecting a time delay according to the difference, at least one of a signal transmitted to the magnitude modulator and the phase modulator when the time delay occurs. And adjusting the time offset. .

A portable terminal including a polar transmitter capable of performing time delay compensation according to an exemplary embodiment of the present invention for achieving the above object includes a radio frequency unit including a polar transmitter and a time delay compensation of the polar transmitter. A baseband signal processor for generating a pulse modulated signal and transmitting and controlling a time offset when the pulse modulated signal is transmitted to at least one of the magnitude modulator and the phase modulator, and controlling signal generation of the baseband signal processor And a terminal control unit, wherein the polar transmitter outputs a magnitude modulation unit generating and outputting a magnitude modulation signal from the pulse modulation signal, a phase modulation unit generating and outputting a phase modulation signal from the pulse modulation signal, and an output of the magnitude modulation unit. And compare the output of the phase modulator with each other And a time delay compensation unit for differentially amplifying the difference and transferring the difference to the baseband signal processing unit, wherein the baseband signal processing unit detects a time delay occurrence according to the type of the differentially amplified signal, and determines whether or not the detected time delay occurs. And adjusting a time offset of at least one of the signal transmitted to the magnitude modulator and the phase modulator.

The magnitude modulator generates and outputs a magnitude modulated signal from the pulse modulated signal, and the phase modulator generates and outputs a phase modulated signal from the pulse modulated signal.

The time delay compensator compares a first envelope detector for detecting an envelope of the magnitude modulated signal, a second envelope detector for detecting an envelope of the phase modulated signal, and an output of the first envelope detector and a reference signal. A first comparator for outputting a signal of a predetermined level, a second comparator for outputting a signal of a predetermined level according to a comparison result by comparing the output of the second envelope detector with a reference signal, and the first comparator and the second comparator It may include a differential amplifier to amplify the difference in output and transmits to the baseband signal processor.

The polar transmitter may further include a power amplifier configured to power amplify the output of the magnitude modulator and the phase modulator, and disposed between the magnitude modulator and the first envelope detector to control the magnitude according to the control of the baseband signal processor. A first switch for controlling a modulated signal to flow in the direction of the first envelope detector, and disposed between the phase modulator and the second envelope detector to transmit the phase modulated signal to the second envelope detector according to control of the baseband signal processor; It may further include a second switch for controlling to flow in the direction.

And the first switch includes the magnitude modulator, the first envelope detector, a first comparator, and a differential amplifier under control of the baseband signal processor under control of the terminal controller while the pulse modulated signal is supplied. And a path including the magnitude modulator, the first switch, and the power amplifier under the control of the baseband signal processor under control of the terminal controller when a data signal or a voice signal to be transmitted to the outside is transmitted. The second switch of the terminal control unit when the data signal or the voice signal to be transmitted to the phase modulation unit, the external control unit under the control of the baseband signal processor under the control of the terminal control unit while the pulse modulation signal is supplied. A second envelope detector, a second comparator, and a differential amplifier under control. May form a path, and may include a path including a phase modulator, a second switch, and a power amplifier.

In addition, the portable terminal inputs an input signal for inputting an entire periodic mode for setting the time delay compensation function while the portable terminal is operating, and performs the time delay compensation function during a period in which the portable terminal does not perform a communication function. The apparatus may further include an input unit configured to generate at least one of an input signal for setting the entire periodic mode input and an input signal for inputting the time delay compensation releasing mode for releasing the time delay compensation function.

According to the present invention, a polar transmitter performing a time delay compensation function, a method of operating the same, and a portable terminal including the same, the present invention provides a method for properly performing time delay compensation of a polar transmitter having a simple structure when transmitting and receiving a signal. Solve problems associated with possible time delays.

1 is a view schematically showing the configuration of a polar transmitter according to an embodiment of the present invention.
2 is a view showing in more detail the configuration of the time delay compensation unit of FIG.
3 is a view for explaining an example of detecting a time delay occurrence in the time delay compensation unit of the present invention;
4 is a flowchart illustrating a time delay compensation method of a polar transmitter according to an embodiment of the present invention;
5 is a diagram schematically illustrating a configuration of a mobile terminal to which a polar transmitter is applied according to an exemplary embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, only parts necessary for understanding the operation according to the embodiment of the present invention will be described, and the description of other parts will be omitted so as not to disturb the gist of the present invention.

The terms or words used in the specification and claims of the present invention described below should not be construed as being limited to ordinary or dictionary meanings, and the inventors should use the concept of terms to explain their own invention in the best way. Based on the principle that it can be properly defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only one of the most preferred embodiments of the present invention, and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

1 is a block diagram schematically illustrating a configuration of a polar transmitter according to an exemplary embodiment of the present invention.

Referring to FIG. 1, a polar transmitter 200 according to an exemplary embodiment of the present invention may include a baseband signal processor 210, a magnitude modulator 220, a phase modulator 230, a time delay compensator 250, and It may include the configuration of the power amplifier 240.

The polar transmitter 200 according to the exemplary embodiment of the present invention having the configuration as described above transmits the signal transmitted from the baseband signal processor 210 to the time delay compensator 250 through the magnitude modulator 220. The circuit is arranged such that the signal transmitted by the band signal processor 210 is transmitted to the time delay compensator 250 through the phase modulator 230. The amplitude modulated signal output from the magnitude modulator 220 and the phase modulated signal output from the phase modulator 230 are power amplified through the power amplifier 240 and then the antenna is transmitted to the time delay compensator 250. It propagates through the air. In this process, the baseband signal processor 210 of the polar transmitter 200 may detect a time delay using a pulse modulated signal capable of detecting a time delay occurrence. That is, the baseband signal processor 210 may control to compensate the time delay of the magnitude modulated signal and the phase modulated signal according to the time delay signal fed back by the time delay compensator 250 during the pulse modulation signal input period. Hereinafter, each configuration of the polar transmitter 200 will be described in more detail.

The baseband signal processor 210 generates a baseband signal corresponding to a voice signal or a data signal to be transmitted to the outside under the control of the terminal controller of the terminal. The baseband signal processor 210 may transfer the generated baseband signal to the magnitude modulator 220 and the phase modulator 230. In particular, the baseband signal processor 210 generates a pulse modulated signal to compensate for the phase delay of the signal passing through the magnitude modulator 220 and the phase modulator 230, and converts the generated pulse modulated signal into the magnitude. The signal may be transmitted to the time delay compensator 250 through the modulator 220 and the phase modulator 230. In this case, the pulse modulated signal may be a square wave signal of a predetermined form generated by the baseband signal processor 210 as a test signal for detecting a time delay occurrence. A signal transmitted through the magnitude modulator 220 and then transmitted to the time delay compensator 250 and a signal transmitted to the time delay compensator 250 through the phase modulator 230 are respectively a specific reference signal. Is converted to a constant output value. The output value may be differentially amplified and then fed back to the baseband signal processor 210. The baseband signal processor 210 may control to compensate for the time delay of the generated baseband signal by checking the differentially amplified and fed back signal. To this end, the baseband signal processor 210 determines a time offset adjustment value of a signal transmitted to the magnitude modulator 220 and the phase modulator 230 based on the signal fed back from the time delay compensator 250. Can be. The baseband signal processor 210 adjusts a time offset value of a signal corresponding to data or voice to be transmitted to the outside by the terminal controller of the terminal based on the time offset adjustment value, and then modulates the amplitude modulator 220. And a signal to the phase modulator 230. The baseband signal processor 210 may include a buffer 1 and a buffer 2, respectively, in order to transmit a signal to the magnitude modulator 220 and the phase modulator 230. The baseband signal processor 210 adjusts the time offset value by adjusting the size of one of the buffer 1 and the buffer 2.

The magnitude modulator 220 generates a magnitude modulated signal from a signal transmitted by the baseband signal processor 210. The signal passing through the magnitude modulator 220 may be input to the power amplifier 240 via the time delay compensator 250. On the other hand, when the pulse modulated signal is output from the baseband signal processor 210, the signal passed through the magnitude modulator 220 is converted into a constant output value through the time delay compensator 250 and then the baseband signal processor Is returned to 210. Accordingly, the signal to be transmitted to the outside of the signal passing through the magnitude modulator 220 propagates to the outside through the power amplifier 240, but is generated for time delay compensation of the signal passed through the magnitude modulator 220. The pulse modulated signal is fed back to the baseband signal processor 210 via the time delay compensation unit 250 without propagating to the outside. On the other hand, the baseband signal processor may set the time offset of the pulse modulated signal transmitted to the magnitude modulator 220 to "0" to confirm whether a time delay occurs. When the time delay occurs, the baseband signal processor 210 adjusts the signal time offsets transmitted to the magnitude modulator and the phase modulator.

The phase modulator 230 generates a phase modulated signal from a signal transmitted by the baseband signal processor 210. The signal passing through the phase modulator 230 may be input to the power amplifier 240 via the time delay compensator 250. Thereafter, the phase modulated signal may be propagated to the outside after the magnitude is modulated in response to the output of the magnitude modulator 220 connected to the other end of the power amplifier 240. Meanwhile, similar to the magnitude modulator 220, when the pulse modulated signal is output from the baseband signal processor 210, the signal that has passed through the phase modulator 230 passes through the time delay compensator 250. After converted to a value, it is fed back to the baseband signal processor 210. Substantially, the signal fed back to the baseband signal processor 210 may be a result of comparing values corresponding to the envelope of the magnitude modulated signal and the phase modulated signal while the pulse modulated signal is supplied. Accordingly, the signal that the terminal controller of the terminal intends to transmit to the outside among the signals passing through the phase modulator 230 is propagated to the outside through the power amplifier 240, but the time delay among the signals passed through the phase modulator 230 is delayed. The pulse modulated signal generated for compensation is fed back to the baseband signal processor 210 without propagating to the outside. The baseband signal processor may set the time offset of the pulse modulated signal transmitted to the phase modulator 230 to “0” to confirm whether a time delay occurs. The baseband signal processor 210 may adjust a time offset value of the phase modulated signal transmitted to the phase modulator 230. The time offset value is adjusted to compensate for the time delays of the magnitude modulator 220 and the phase modulator 230, and is transmitted to at least one of the magnitude modulator 220 and the phase modulator 230. The time delay can be compensated by adjusting the time offset of the signal.

The time delay compensator 250 has an output terminal of the magnitude modulator 220 and an output terminal of the phase modulator 230, and is connected to the baseband signal processor 210 and the power amplifier 240. In this case, the time delay compensator 250 transmits the corresponding signals to the power amplifier 240 according to the type of the signal transmitted through the magnitude modulator 220 and the signal transmitted through the phase modulator 230. Alternatively, the baseband signal processing unit 210 may be controlled to feedback. In this case, the time delay compensator 250 is a signal and the phase modulation transmitted from the magnitude modulator 220 under the control of the terminal including the baseband signal processor 210 or the baseband signal processor 210. The signal transmitted from the unit 230 may be transmitted to the power amplifier 240 or may be fed back to the baseband signal processor 210. In other words, when the signal transmitted from the magnitude modulator 220 and the signal transmitted from the phase modulator 230 are pulse modulated signals for time delay compensation, the time delay compensator 250 may mutually exchange the corresponding signals. The comparison result may be transmitted to the baseband signal processor 210. The time delay compensator 250 controls to transmit each signal to the power amplifier 240 when the signal transmitted from the magnitude modulator 220 and the phase modulator 230 is a signal to be transmitted to the outside. can do. To this end, the time delay compensator 250 may include a first switch 201, a first envelope detector 211, a first comparator 221, a second switch 202, and a second envelope. The detector 212, the second comparator 222, and the differential amplifier 205 may be configured.

Referring to FIG. 2, among the components of the time delay compensator 250 of the present invention, the first switch 201 includes the magnitude modulator 220, the first envelope detector 211, and the power amplifier 240. Is placed in between. The first envelope detector 211 is disposed between one end of the first switch 201 and the first comparator 221. The output of the first comparator 221 may be input to one port of the differential amplifier 205. The second switch 202 is disposed between the phase modulator 230, the second envelope detector 212, and the power amplifier 240. The second envelope detector 212 is disposed between one end of the second switch 202 and the second comparator 222, and an output of the second comparator 222 is one end of the differential amplifier 205. Can be entered. The differential amplifier 205 may perform differential amplification on the output of the first comparator 221 and the output of the second comparator 222, and may transmit the differentially amplified signal to the baseband signal processor 210. have.

Meanwhile, the first switch 201 may transfer a signal transmitted from the magnitude modulator 220 to the first envelope detector 211 or to the power amplifier 240 under the control of the baseband signal processor 210. have. That is, the first switch 201 transfers the pulse modulated signal to the magnitude modulator 220 to the first envelope detector 211. The first switch 201 may transfer the size-modulated data signal or the voice signal from the magnitude modulator 220 to the power amplifier 240.

The second switch 202 may transfer a signal transmitted from the phase modulator 230 to the second envelope detector 212 or to the power amplifier 240 under the control of the baseband signal processor 210. . That is, when the pulse modulated signal is transmitted to the phase modulator 230, the second switch 202 transmits the signal to the second envelope detector 212. In addition, the second switch 202 may transfer the phase modulated data signal or the voice signal from the phase modulator 230 to the power amplifier 240.

The first envelope detector 211 receives a magnitude modulated signal transmitted from the first switch 201. The first envelope detector 211 detects an envelope of the magnitude modulation signal and transfers the detected envelope to the first comparator 221. The first envelope detector 211 is configured to add the same time delay as the second envelope detector 212 for detecting the envelope of the phase modulated signal.

The second envelope detector 212 receives a phase modulated signal transmitted from the second switch 202. In addition, the second envelope detector 212 may detect an envelope of the phase modulated signal and transmit the detected envelope to the second comparator 222.

The first comparator 221 compares the envelope transmitted from the first envelope detector 211 with a reference signal, and transmits a high signal, for example, a 5V signal, to the differential amplifier 205 when it is larger than the reference signal. Can be. When the envelope signal is smaller than the reference signal, the first comparator 221 may transmit a low signal, for example, a 0V signal, to the differential amplifier 205.

The second comparator 222 may compare the envelope transmitted from the second envelope detector 212 with a reference signal, and transmit a high signal to the differential amplifier 205 when it is larger than the reference signal. The second comparator 222 may transmit a low signal to the differential amplifier 205 when the envelope signal is smaller than the reference signal.

The differential amplifier 205 may subtract the output of the first comparator 221 and the output of the second comparator 222, amplify the subtracted signal, and transfer the amplified signal to the baseband signal processor 210. For example, when the output of the first comparator 221 and the output of the second comparator 222 coincide with each other, the differential amplifier 205 outputs the output of the first comparator 221 and the second comparator 222. ) Are subtracted from each other to transmit a DC voltage without a pulse to the baseband signal processor 210. When the output of the first comparator 221 and the output of the second comparator 222 do not coincide with each other due to a time delay, the differential amplifier 205 may output a pulse signal having a constant width to the baseband signal processor 210. Can be delivered to. The baseband signal processor 210 may determine that no time delay occurs when receiving a signal corresponding to a DC voltage, that is, a constant value, from the differential amplifier 205. When the baseband signal processor 210 receives a pulse signal having a predetermined width from the differential amplifier 205, the baseband signal processor 210 may determine that a time delay has occurred and determine a time offset adjustment value corresponding to the width of the pulse signal. .

Meanwhile, in the above description, a configuration of disposing the first switch 201 and the second switch 202 such that the pulse modulated signal generated for the time delay compensation does not propagate to the outside through the power amplifier 240 will be described. However, the present invention is not limited thereto. That is, the polar transmitter 200 according to an exemplary embodiment of the present invention omits the configuration of the first switch 201 and the second switch 202 and the first envelope detector 211 together with the power amplifier 240. The second envelope detector 212 may be arranged to be connected to the magnitude modulator 220 in parallel, and the second envelope detector 212 may be arranged to be connected to the phase modulator 230 in parallel with the power amplifier 240. In this case, a pulse modulated signal from the baseband signal processor 210 may be transmitted to the first envelope detector 211 and the second envelope detector 212, and may also be propagated to the outside through the power amplifier 240. Accordingly, the time delay compensator 250 of the present invention will be described as an example of disposing the first switch 201 and the second switch 202 to prevent external propagation of the pulse modulated signal. Therefore, the polar transmitter 200 of the present invention may perform the time delay compensation even if the configuration of the first switch 201 and the second switch 202 is excluded. Here, when the first switch 201 and the second switch 202 are excluded, while the signals corresponding to data and voice are output through the baseband signal processing unit 210, the distinction between the start and end of the corresponding signals is divided. Since the baseband signal processor 210 may not accurately determine the time offset adjustment value for time delay compensation only when a certain square wave shape is detected among the outputs of the differential amplifier 205. Next, the input and output of the differential amplifier 205 will be described in more detail with reference to FIG. 3.

3 is a view for explaining the output of the first comparator 221 and the second comparator 222 and the output of the differential amplifier 205 according to an embodiment of the present invention. In the following description, it is assumed that the baseband signal processor 210 generates and supplies a pulse modulated signal for time delay compensation.

Referring to FIG. 3, first, there is no time delay between a signal transmitted to the first comparator 221 through the magnitude modulator 220 and a signal transmitted to the second comparator 222 through the phase modulator 230. In the case of the 301 waveform diagram, a DC voltage having a constant value may be output to the output of the differential amplifier 205. That is, when there is no time delay, the difference between the output of the first comparator 221 and the second comparator 222 does not occur, so that the differential amplifier 205 outputs the output of the first comparator 221 and the second. A low signal corresponding to a value, for example, 0V, having no difference in the output of the comparator 222 may be transmitted to the baseband signal processor 210.

On the other hand, when a time delay occurs between the signal transmitted to the first comparator 221 via the magnitude modulator 220 and the signal transmitted to the second comparator 222 via the phase modulator 230, As such, the output of the differential amplifier 205 may generate a pulse signal of a certain type. In more detail, when the signal input to the first comparator 221 has a constant time delay, the first comparator 221 outputs a time delayed square wave signal as shown. When the signal input to the second comparator 222 occurs with a time delay from the signal input to the first comparator 221, the second comparator 222 is the first comparator 221 as shown. It is possible to output a square wave having a time delay different from that of. Then, the differential amplifier 205 subtracts the output of the first comparator 221 and the output of the second comparator 222 to generate a pulse signal having a predetermined width as shown, and the baseband signal processor 210 ) Can be delivered.

Accordingly, the baseband signal processor 210 may identify a signal transmitted from the differential amplifier 205 and recognize a width of a pulse signal having a predetermined width as a time delay. In this case, the baseband signal processor 210 may process the signal of the differential amplifier 205 by A / D conversion. Thereafter, the baseband signal processor 210 determines a time offset for a time delay corresponding to the predetermined width, and transmits the determined time offset value to the magnitude modulator 220 and the phase modulator 230. Can be controlled to apply to the signal. Then, since the magnitude modulator 220 and the phase modulator 230 receive the pulse modulated signal to which the time offset is applied, the magnitude modulator 220 and the phase modulator 230 receive the signal whose time delay is compensated. The differential amplifier 205, which passes to the first comparator 221 and the second comparator 222 and receives the outputs of the first comparator 221 and the second comparator 222, has a time as shown in the 301 waveform diagram. A signal having a signal constant value without delay may be transmitted to the baseband signal processor 210.

Meanwhile, the baseband signal processor 210 controls the first switch 201 and the second switch 202 so that the terminal detects the time offset value for the above-described time delay compensation process even while the terminal performs communication. Can be controlled. In addition, the baseband signal processing unit 210 may detect the time offset value for the time delay compensation process when the terminal does not support the communication function but maintains the turn-on state. The baseband signal processor 210 may perform a process of detecting a time offset value for the time delay compensation process according to a predetermined period to control the time offset value to be continuously updated. Accordingly, since the baseband signal processor 210 applies a time offset value for the time delay compensation process to the data or the voice output signal of the baseband signal processor 210, the magnitude modulator 220 and the phase modulator ( The signal transmitted to 230 may control an external transmission signal without a time delay to be transmitted to the power amplifier 240.

In addition, the time delay compensator 250 of the present invention has a time delay from the magnitude modulator 220 to the input terminal of the differential amplifier 205 and a time delay from the phase modulator 230 to the input terminal of the differential amplifier 205. It can be configured to be the same. Therefore, the addition of the first switch 201, the first envelope detector, the first comparator 221, the second switch 202, the second envelope detector 212, the second comparator 222 and the differential amplifier 205 It does not affect the measurement of the time delay of the magnitude modulation path and the time delay of the phase modulation path.

In the above, the configuration of the polar transmitter 200 and the roles of the components of the polar transmitter 200 according to an exemplary embodiment of the present invention have been described. Hereinafter, a method for time delay compensation of the polar transmitter 200 according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

4 is a flowchart illustrating a time delay compensation method of a polar transmitter according to an embodiment of the present invention.

Referring to FIG. 4, in the time delay compensation method of the polar transmitter of the present invention, the baseband signal processor 210 generates a pulse modulated signal for detecting a time delay in step 401. As described above, the pulse modulated signal is a signal randomly generated to compensate for the time delay of the polar transmitter 200 and may be a square wave signal having a high level section and a low level section. The length of the pulse modulated signal may also be arbitrarily determined by the baseband signal processor 210, and the minimum length for detecting a time delay delay, for example, one low level section and one high level section. It is desirable to have one or more cycles.

Next, when the baseband signal processor 210 generates a pulse modulated signal, the baseband signal processor 210 transmits the generated pulse modulated signal to the magnitude modulator 220 and the phase modulator 230. Accordingly, as in step 403, the magnitude modulator 220 generates a magnitude modulated signal from the pulse modulated signal transmitted from the baseband signal processor 210. The phase modulator 230 may generate a phase modulated signal from the pulse modulated signal transmitted from the baseband signal processor 210.

In this process, the baseband signal processing unit 210 may control to initialize the time offset of the signal transmitted to the magnitude modulation signal unit 220 and the phase modulation unit 230 as in step 405. That is, the time offset of the signal transmitted to the magnitude modulator 220 and the phase modulator 230 may be set to “0”. The initialization of the time offset is for detecting the occurrence of time delay between the signal output through the magnitude modulator 220 and the signal output through the phase modulator 230.

Next, the magnitude modulated signal and the phase modulated signal are transmitted to the time delay compensator 250 in step 407. That is, the magnitude modulation signal in which the time offset output from the magnitude modulation unit 220 is initialized is differential amplifier through the first switch 201, the first envelope detector 211, and the first comparator 221 shown in FIG. 2. Is passed to 205. In addition, the phase modulated signal from which the time offset is initialized and output from the phase modulator 230 is transmitted through the second switch 202, the second envelope detector 212, and the second comparator 222 illustrated in FIG. 2. Is passed to 205. Then, the differential amplifier 205 performs differential amplification on the output of the first comparator 221 and the output of the second comparator 222, and transmits the differentially amplified signal to the baseband signal processor 210. Can be.

In step 409, the baseband signal processor 210 checks the differentially amplified signal transmitted from the time delay compensator 250 to determine whether the shape of the pulse modulated signal is changed. That is, the baseband signal processor 210 may check whether the output of the differential amplifier 205 is a constant value.

If the output value of the differential amplifier 205 is not a constant value (ie, a signal having a constant pulse width) in step 409, the baseband signal processing unit 210 enters step 411 and determines that a time delay has occurred. The time offset adjustment value is determined according to the width, and the time offset value adjustment of the signal transmitted to the magnitude modulator 220 and the phase modulator 230 is controlled based on the determined time offset adjustment value.

On the other hand, if the output value of the differential amplifier 205 is a constant value in step 409, the baseband signal processing unit 210 is time to the signal output through the magnitude modulator 220 and the phase modulator 230 in step 413 It can be determined that no delay has occurred.

Thereafter, the baseband signal processor 210 checks whether the time delay compensation application period has arrived in step 415, and if the time delay compensation application period does not arrive, branching to step 415 to continuously check step 415. Can be. Meanwhile, when the time delay compensation application period arrives in step 415, the baseband signal processor 210 may return to step 401 to repeatedly perform the following process. The time delay compensation application period may be a predetermined period, for example, a predetermined time unit. In addition, the application time of the time delay compensation application period may be a time when the terminal adopting the polar transmitter 200 does not use the communication function, and may also be repeatedly performed in a certain period unit even when using the communication function. There will be. Ideally, the time when the communication function is not performed is preferably set as a period of time delay application, but the present invention supports performing time delay compensation even while the communication function is performed using the switches.

As described above, in the time delay compensation method of the polar transmitter 200 according to the exemplary embodiment of the present invention, a time offset of a signal through a magnitude modulation path and a signal through a phase modulation path using a pulse modulated signal for time delay compensation By confirming the time delay can be confirmed, and corresponding time offset adjustment can be performed to compensate for the time delay.

FIG. 5 is a diagram illustrating a case of a mobile terminal in which a polar transmitter according to an embodiment of the present invention is applied to a radio frequency unit.

Referring to FIG. 5, the mobile terminal 100 of the present invention includes a radio frequency unit 110 to which a polar transmitter 200 is applied, an input unit 120, an audio processor 130, a display unit 140, and a storage unit 150. ) And the terminal control unit 160.

The portable terminal 100 of the present invention having such a configuration performs time delay compensation of the polar transmitter 200 under the control of the terminal controller 160, and transmits a data signal or a voice signal according to the radio frequency. It may be performed based on the unit 110. In this case, the terminal control unit 160 is provided to the magnitude modulator 220 and the phase modulator 230 through the baseband signal processor 210 of the polar transmitter 200 to compensate for the time delay of the polar transmitter 200. Time offset control of the transmitted signal may be performed. Meanwhile, when the terminal controller 160 performs time delay compensation of the polar transmitter 200, the time delay compensator 250 outputs the output of the differential amplifier 205 through the baseband signal processor 210. It may be delivered to the terminal controller 160 or directly to the terminal controller 160. Here, the terminal controller 160 is a configuration for controlling the operation of the components of the portable terminal 100 and includes a configuration of the baseband signal processor 210 included in the polar transmitter 200 or the base The band signal processor 210 may be configured to control the band signal processor 210. That is, when the baseband signal processor 210 is included in the terminal controller 160, the terminal controller 160 generates and transmits a pulse modulated signal and the time delay of the baseband signal processor 210. And the determination of the offset adjustment value for time delay compensation and the application of the offset adjustment value. The terminal controller 160 may perform signal conversion, which is a function of the baseband signal processor 210, to transmit data signals and voice signals to the magnitude modulator 220 and the phase modulator 230. Here, when the baseband signal processor 210 is included as a configuration of the terminal controller 160, the polar transmitter 200 may be understood as a configuration including components other than the baseband signal processor 210. .

Hereinafter, each configuration of the mobile terminal 100 will be described in detail.

The radio frequency unit 110 is a configuration for supporting the communication service of the mobile terminal 100. The radio frequency unit 110 may be in the form of a modem that can support at least one of a variety of communication methods, for example, a mobile communication modem such as CDMA, WCDMA, GSM, mobile data communication modem such as HSDPA, Wibro And so on. The radio frequency unit 110 performs the formation of a communication channel for a voice call and the transmission of an image or an image or the formation of a communication channel for data transmission based on data transmission and reception under the control of the terminal controller 160. That is, the radio frequency unit 110 forms a voice call channel, a data communication channel, a video call channel, and the like between communication systems. The radio frequency unit 110 may include a polar transmitter 200 and a receiver 300. The polar transmitter 200 may perform the time delay compensation described with reference to FIGS. 1 to 4. In this case, the polar transmitter 200 may detect and apply a time offset adjustment value based on a pulse modulated signal generated and transmitted by the baseband signal processor 210 under the control of the terminal controller 160. The polar transmitter 200 converts the corresponding signal into the baseband signal based on the baseband signal processor 210 when the data signal or the voice signal is transmitted under the control of the terminal controller 160, and compensates for the time delay. The magnitude modulating signal 220 and the phase modulating signal 230 to which the time offset adjustment value is applied may be used to generate the magnitude modulation signal and the phase modulation signal, respectively. In addition, the polar transmitter 200 may propagate the magnitude and phase modulated signal to the outside through the power amplifier 240. The receiver 300 may receive a signal propagated by the other portable terminal to the polar transmitter 200 and transmit the signal to the terminal controller 160.

The input unit 120 includes a plurality of input keys and function keys for receiving numeric or character information and setting various functions. The function keys may include a direction key, a side key, and an accelerator key set for performing a specific function. The input unit 120 may include a side key formed at one side of the touch screen 140 and the case without employing a separate key button or keypad when the portable terminal 100 employs a full touch screen. The input unit 120 may be implemented by setting the key map including a plurality of keys and the touch panel 143 according to the key map when the portable terminal 100 employs the touch screen 140. The keymap may include a qwerty keymap, a 3 * 4 keymap, a 4 * 3 keymap, a menu map, a soft keymap, and the like. In particular, the input unit 120 of the present invention may generate an input signal for adjusting the time delay compensation period of the polar transmitter 200 according to an embodiment of the present invention under user control. That is, the input unit 120 compensates the time delay at a predetermined time period among the input signals for setting the time delay compensation of the polar transmitter 200 at a predetermined time period and when the portable terminal 100 does not operate the communication function. It may generate an input signal and the like for setting to perform. The input unit 120 may support the time period adjustment by transmitting the generated input signal to the terminal controller 160.

The audio processor 130 includes a speaker (SPK) for outputting audio data transmitted / received during a call, audio data included in a received message, and audio data according to reproduction of an audio file stored in the storage 150, and during a call. A microphone (MIC) for collecting the user's voice or other audio signals. The audio processor 130 may output an alarm corresponding to the time delay of the polar transmitter 200. In this case, the alarm according to the time delay of the polar transmitter 200 may be omitted according to a user setting or a designer's intention of the portable terminal 100.

The display unit 140 displays various menus of the mobile terminal 100, information input by the user, information provided to the user, and the like. That is, the display unit 140 may provide various screens according to the use of the mobile terminal 100, for example, a standby screen, a menu screen, a message writing screen, a call screen, and the like. The display unit 140 may be formed of various display elements such as a liquid crystal display (LCD), an organic light emitting diode (OLED), and the like. In addition, the display unit 140 may function as the input unit 120 when the display unit 140 is manufactured in the form of a touch screen together with the touch panel disposed thereon. In particular, the display unit 140 of the present invention may provide a screen interface for setting a time delay compensation period of the polar transmitter 200. As described above, the screen interface for setting the time delay compensation period may be configured in a full cycle mode for controlling time delay compensation according to a predetermined period regardless of whether the communication function is used or not. The display device may include a screen component for allowing a user to select a selection cycle mode for controlling time delay compensation, a time delay compensation release mode, and the like. Meanwhile, when the display unit 140 is set to a mode for performing time delay compensation of the polar transmitter 200, the display unit 140 may output an icon or a message indicating that the current time delay compensation is set. The display unit 140 may output a message indicating that the corresponding time delay compensation is performed when an event for actual time delay compensation occurs while performing the time delay compensation function of the polar transmitter 200. The output of the above message may be omitted according to a user setting or a designer's intention similar to the output of the audio processor 130.

The storage unit 150 may include a key map for operating a touch screen when the portable terminal 100 is formed as a touch screen, including an application program required for operating a function according to an embodiment of the present invention. The keymap may include a keymap, a menu map, a soft keymap, and the like. The key map and the menu map may be in various forms, respectively. In other words, the keymap may be a keyboard map, a 3 * 4 keymap, a QWERTY keymap, or a control keymap for operation control of an currently active application. In addition, the menu map may be a menu map for controlling an application program currently being activated, or may be a menu map having a list of various menus provided by the mobile terminal 100. The storage unit 150 may largely include a program area and a data area.

The program area includes an operating system (OS) for booting the mobile terminal 100 and operating the above-described components, and an application program for playing various files, for example, whether the mobile terminal 100 supports the function. Can store application programs for supporting call functions, web browsers for accessing Internet servers, MP3 applications for playing other sound sources, image output applications for playing pictures, and video playback applications. In particular, the program area of the present invention includes a time delay compensation period setting program.

The time delay compensation period setting program may be loaded into the terminal controller 160 when power is supplied to the portable terminal 100 to support a period for compensating for a time delay of the polar transmitter 200. . That is, the time delay compensation period setting program may include: a routine for outputting a screen interface for setting the time delay compensation period, a routine for checking an entire cycle mode or a selection cycle mode and a time delay compensation release mode setting input through the screen interface; It may include a time delay compensation routine for controlling to perform the time delay compensation function according to the set mode.

The time delay compensation routine is a routine for generating a pulse modulated signal for checking whether a time delay has occurred, a routine for checking the output of the differential amplifier 205 delivered from the differential amplifier 205, and the differential amplifier 205 A routine for determining a time offset adjustment value from an output of the control panel; a routine for controlling the time offset adjustment value to adjust a time offset of a signal transmitted to the magnitude modulator 220 and the phase modulator 230; And a switch control routine for controlling the first switch 201 and the second switch 202. The switch control routine may include the first switch 201 and the second switch such that a pulse modulated signal is fed back to the baseband signal processor 210 through the time delay compensator 250 when the time delay compensation period arrives. Routine for controlling the state of the 202, when the communication function is activated when the time delay compensation period is not the first switch 201 and the second switch to propagate data or voice to the outside under the control of the terminal controller 160 Routine to control the state of 202.

The data area is an area in which data generated according to the use of the mobile terminal 100 is stored, and may store phone book information, at least one icon according to a widget function, and various contents. In addition, the data area may store a user input input through the touch screen when the display unit 140 is manufactured in the form of a touch screen. In particular, the data area of the present invention may temporarily store setting information for the entire periodic mode or the selective periodic mode, an output of the differential amplifier 205, a time offset adjustment value according to the output of the differential amplifier 205, and the like. . The time offset adjustment value stored in the data area may be updated for each time delay compensation period.

The terminal controller 160 supports to perform an initialization process by controlling power supply to each component of the portable terminal 100, and when the initialization process is completed, the polar transmitter 200 according to an embodiment of the present invention for each component. Signal flow for time delay compensation). Hereinafter, the baseband signal processing unit 210 of the polar transmitter 200 will be described as a configuration included in the terminal controller 160. However, the present invention is not limited thereto, and the baseband signal processor 210 is included in the polar transmitter 200 as described above, and according to the control of the terminal controller 160, time delay compensation according to an embodiment of the present invention. It may be possible to perform a signal flow control for.

Meanwhile, in more detail, when the time delay compensation period arrives, the terminal controller 160 generates a pulse modulated signal for checking whether a time delay occurs, and generates the generated pulse modulated signal by the polar transmitter 200. The baseband signal processor 210 may transmit the signal to the baseband signal processor 210. The terminal controller 160 may control to initialize the time offset of the signal transmitted to the magnitude modulator 220 and the phase modulator 230 included in the polar transmitter 200. Thereafter, the terminal controller 160 controls the state of the second switch 202 of the first switch 201 to form a path so that the output of the differential amplifier 205 of the time delay compensator 250 is returned. . Thereafter, the terminal controller 160 can check the output of the differential amplifier 205 to determine whether a time delay has occurred. That is, the terminal controller 160 checks whether the output of the differential amplifier 205 is a constant value. If the output of the differential amplifier 205 is a constant value, it is determined that a time delay does not occur, and if a communication function is activated without a separate time offset adjustment, the data or voice signal is transmitted to the outside according to user control. Can be controlled. Meanwhile, when the output of the differential amplifier 205 is not a constant value, the terminal controller 160 determines a time offset adjustment value corresponding to a deformation state of a pulse width, and sets the time offset adjustment value to the magnitude modulator 220. ) May be controlled to compensate for a time delay of a signal transmitted to at least one of the phase modulator 230. When the communication function is activated, the terminal controller 160 adjusts the states of the first switch 201 and the second switch 202 to propagate the magnitude-modulated and phase-modulated signals to the outside through the power amplifier 240. Can be controlled.

As described above, the mobile terminal 100 according to the embodiment of the present invention performs the time delay compensation of the polar transmitter 200 included in the radio frequency unit 110 at a predetermined period, so that the time delay is increased during signal transmission. It can be controlled so that a normal signal can be sent without occurrence.

As described above, the present invention can detect a time delay without a frequency downlink composed of a mixer, a local oscillator, a filter, and the like, which is conventionally used in the polar transmitter 200, and a complex signal processing technique that is conventionally performed by the baseband signal processor. It also uses a simple hardware configuration to measure and compensate for time delay mismatch in polar transmitters.

In the meantime, the above-described portable terminal 100 may be provided by a short-range communication module for short-range communication, a camera module for capturing still images / videos of a subject, and a wired communication method or a wireless communication method of the portable terminal 100. Configurations not mentioned above may be included, such as an interface for data transmission and reception, an Internet communication module performing an Internet function by communicating with an Internet network, and a digital broadcasting module performing a digital broadcast reception and playback function. These components can not be enumerated because all of them vary according to the convergence trend of digital devices, but the components equivalent to those mentioned above may be further included in the device. have. In addition, the mobile terminal 100 of the present invention may be excluded from the above configuration or replaced by another configuration, depending on the form of the present invention. Which will be readily apparent to those skilled in the art.

In addition, the portable terminal 100 according to the embodiment of the present invention may include any type of device to which the polar transmitter can be applied. For example, the portable terminal 100 includes all mobile communication terminals operating based on communication protocols corresponding to various communication systems, including a portable multimedia player (PMP), Digital communication player, PDA (Personal Digital Assistant), music player (e.g. MP3 player), mobile game terminal, smart phone, notebook and handheld PC, and all information and communication devices and multimedia devices It may include an application device.

While the present invention has been described with reference to several preferred embodiments, these embodiments are illustrative and not restrictive. It will be understood by those of ordinary skill in the art that various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.

100: portable terminal 110: radio frequency unit
120: input unit 130: audio processing unit
140: display unit 150: storage unit
160: terminal control unit 200: polar transmitter
210: baseband signal processing unit 220: magnitude modulation unit
230: phase modulator 240: power amplifier
250: time delay compensation unit 201: first switch
202: second switch 211: first envelope detector
212: second envelope detector 221: first comparator
222: second comparator 205: differential amplifier
300 receiver

Claims (15)

A baseband signal processor for outputting a pulse modulated signal for detecting a time delay occurrence;
A magnitude modulator for generating and outputting a magnitude modulated signal from the pulse modulated signal;
A phase modulator for generating and outputting a phase modulated signal from the pulse modulated signal;
And a time delay compensator for comparing the output of the magnitude modulator and the output of the phase modulator with each other, differentially amplifying the difference, and transferring the difference to the baseband signal processor.
The baseband signal processor detects a time delay occurrence according to the type of the differentially amplified signal, and determines a time offset of a signal transmitted to at least one of the magnitude modulator and the phase modulator according to whether the detected time delay occurs. A polar transmitter for performing time delay compensation. The method of claim 1,
And the baseband signal processor adjusts a time offset of a signal transmitted to at least one of the magnitude modulator and the phase modulator. The method of claim 1,
The time delay compensation unit
A first envelope detector for detecting an envelope of the magnitude modulated signal;
A second envelope detector for detecting an envelope of the phase modulated signal;
A first comparator comparing the output of the first envelope detector with a reference signal and outputting a predetermined level of signal according to a comparison result;
A second comparator comparing the output of the second envelope detector with a reference signal and outputting a signal having a predetermined level according to a comparison result;
And a differential amplifier amplifying a difference between the outputs of the first comparator and the second comparator and transferring the difference between the outputs of the first comparator and the second comparator. The method of claim 3,
And a power amplifier for power amplifying the outputs of the magnitude modulator and the phase modulator. The method of claim 4, wherein
A first switch disposed between the magnitude modulator and the first envelope detector to control the magnitude modulated signal to flow toward the first envelope detector according to the baseband signal processor;
And a second switch disposed between the phase modulator and the second envelope detector to control the phase modulated signal to flow in the direction of the second envelope detector according to the control of the baseband signal processor. Polar transmitter that performs time delay compensation. The method of claim 5,
The first switch is
While the pulse modulated signal is supplied, a path including the magnitude modulator, the first envelope detector, the first comparator, and the differential amplifier is formed under control of the baseband signal processor, and a data signal or a voice signal to be transmitted to the outside is When transmitted, according to the control of the baseband signal processor to form a path including the magnitude modulator, the first switch, a power amplifier,
The second switch is
While the pulse modulated signal is supplied, a path including the phase modulator, the second envelope detector, a second comparator, and a differential amplifier is formed under control of the baseband signal processor, and a data signal or a voice signal to be transmitted to the outside is And the second switch forms a path including a phase modulator, a second switch, and a power amplifier according to the control of the baseband signal processor. Generating a pulse modulated signal for checking for occurrence of a time delay;
Generating a magnitude modulated signal of which the magnitude of the pulse modulated signal is modulated and a phase modulated signal of which the phase of the pulse modulated signal is modulated;
Initializing a time offset of a signal transmitted to at least one of the magnitude modulation signal unit and the phase modulation unit;
A time delay detection process of comparing the magnitude modulated signal with the phase modulated signal to check a difference, and detecting whether a time delay has occurred according to the difference;
Adjusting the time offset of at least one of the magnitude modulated signal unit and the signal transmitted to the phase modulator when the time delay occurs. The method of claim 7, wherein
The time delay detection process
Detecting envelopes of the magnitude modulated signal and the phase modulated signal;
Comparing the envelopes with a preset reference signal and outputting a signal having a predetermined level according to a comparison result;
Amplifying the difference between the output signals;
Confirming the time delay by checking the differentially amplified signal; time delay compensation method of a polar transmitter comprising a. The method of claim 8,
The confirmation process
Determining that a time delay has occurred when the differentially amplified signal is a pulse modulated signal;
And determining that no time delay occurs when the differentially amplified signal has a constant value. The method of claim 8,
Switching the magnitude modulated signal and the phase modulated signal to flow only in the direction of an envelope detector provided for the envelope detection while the pulse modulated signal is supplied; or
Generating a modulated signal and a phase modulated signal when a data signal or a voice signal transmitted to the outside is transmitted, and switching the generated signals to be amplified by power amplification; Time delay compensation method of the polar transmitter, characterized in that. A radio frequency unit including a polar transmitter;
And a terminal controller configured to generate a pulse modulated signal to perform time delay compensation of the polar transmitter.
The polar transmitter
A magnitude modulation unit generating and outputting a magnitude modulation signal from the pulse modulation signal, a phase modulation unit generating and outputting a phase modulation signal from the pulse modulation signal, and comparing an output of the magnitude modulation unit and an output of the phase modulation unit A time delay compensator for differentially amplifying the difference and transferring the difference to the terminal controller;
The terminal controller detects a time delay occurrence according to the type of the differentially amplified signal, and adjusts a time offset of at least one of signals transmitted to the magnitude modulator and the phase modulator according to whether the detected time delay occurs. A mobile terminal comprising a polar transmitter for performing time delay compensation. The method of claim 11,
The time delay compensation unit
A first envelope detector for detecting an envelope of the magnitude modulated signal;
A second envelope detector for detecting an envelope of the phase modulated signal;
A first comparator comparing the output of the first envelope detector with a reference signal and outputting a predetermined level of signal according to a comparison result;
A second comparator comparing the output of the second envelope detector with a reference signal and outputting a signal having a predetermined level according to a comparison result;
And a differential amplifier for amplifying a difference between the outputs of the first comparator and the second comparator and transferring the difference between the outputs of the first comparator and the second comparator. The method of claim 12,
And a power amplifier configured to power amplify outputs of the magnitude modulator and the phase modulator.
A first switch disposed between the magnitude modulator and the first envelope detector to control the magnitude modulated signal to flow toward the first envelope detector according to the control of the terminal controller;
A second switch disposed between the phase modulator and the second envelope detector and configured to control the phase modulated signal to flow in the direction of the second envelope detector according to the control of the terminal controller; A mobile terminal comprising a polar transmitter for performing compensation. The method of claim 13,
The first switch is
While the pulse modulated signal is supplied, a path including the magnitude modulator, the first envelope detector, the first comparator, and the differential amplifier is formed under control of the terminal controller, and a data signal or a voice signal to be transmitted to the outside is transmitted. In this case, a path including the magnitude modulator, the first switch, and the power amplifier is formed under the control of the terminal controller.
The second switch is
The second envelope detector, the second comparator, and the differential amplifier are controlled according to the control of the terminal control unit when the phase modulation unit, a data signal or an audio signal to be transmitted to the outside is transmitted under the control of the terminal control unit while the pulse modulation signal is supplied. And a polar transmitter for performing time delay compensation, wherein the path includes a path including a phase modulator, a second switch, and a power amplifier. The method of claim 11,
An input signal for inputting an entire periodic mode to set a time delay compensation function while the portable terminal is operating;
An input signal for inputting an entire periodic mode to set the time delay compensation function during a period in which the portable terminal does not perform a communication function;
An input signal for inputting a time delay compensation releasing mode for releasing the time delay compensation function; And a polar transmitter for performing time delay compensation, the input unit generating at least one of the at least one according to a user control.

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