Abstract:
There is a need for a method capable of distinguishing even a temperature difference between a susceptor surface and a wafer surface, and controlling the temperature by reflecting the temperature difference. To accomplish such a purpose, the invention provides a temperature control method of a chemical vapor deposition device that comprises: a chamber; a susceptor which is positioned on the inner side of the chamber to allow rotation therein, wherein a wafer is stacked on an upper side; a gas supplier which is disposed on the inner side of the chamber, and sprays gas toward the wafer; a heater which is disposed on the inner side of the susceptor, and heats the wafer; and a temperature sensor which is positioned in the chamber, and measures the temperature. The temperature control method comprises the steps of: (a) calculating the temperature distribution of the susceptor on the basis of a measured value of the temperature sensor, and dividing a section with relatively high temperature as a susceptor section and a section with relatively low temperature as a wafer section from the temperature distribution; and (b) controlling the heater by comparing a preset reference temperature with the temperature of a selected position of the susceptor section or the wafer section.

Description:
BACKGROUND OF THE INVENTION 
       [0001]    1. Field of the Invention 
         [0002]    The present invention relates to a temperature control method of a chemical vapor deposition device and, more particularly, to a temperature control method which is capable of precisely measuring a temperature distribution at the top surface of a susceptor and also precisely controlling a temperature at the top surface of the susceptor. 
         [0003]    2. Discussion of the Related Art 
         [0004]    A chemical vapor deposition device is used to deposit a thin film on a surface of a semiconductor wafer. A desired thin film is deposited on wafers placed in a susceptor by blowing a process gas into a chamber through gas suppliers. 
         [0005]    In depositing the thin film, adequate internal temperature is very important because it has a great effect on the quality of the thin film. In particular, in metal organic chemical vapor deposition (MOCVD), a high efficiency light-emitting device can be obtained only when temperature control is effectively performed. 
         [0006]    For effective temperature control, first, a temperature distribution at the top surface of a susceptor must be able to be precisely checked. This is because the amount of electric power to be supplied to heaters can be checked only when an accurate temperature distribution is checked. 
         [0007]    There may be a specific temperature difference between a surface temperature in a plurality of wafers loaded into the top surface of the susceptor and a surface temperature of the susceptor. According to the prior art, temperature control is performed by not distinguishing a temperature in the susceptor surface and a temperature in the wafer surface from each other. 
         [0008]    In order to produce a higher-efficiency and higher-quality thin film, it is s necessary to precisely perform temperature control by accurately checking a difference in the surface temperature. 
         [0009]    There is, however, a problem in that very complicated and expensive equipment must be additionally installed in order to check the difference in the temperature. 
       SUMMARY OF THE INVENTION 
       [0010]    There is a need for a method of accurately checking a temperature distribution at the top of a susceptor in order to produce a high quality thin film. 
         [0011]    More particularly, there is a need for a temperature control method, which is capable of distinguishing a temperature in a susceptor surface and a temperature in a wafer surface from each other and of taking the temperature difference into consideration. 
         [0012]    Furthermore, there is a need for a method capable of checking a temperature difference between a susceptor surface and a wafer surface without additional complicated and expensive equipment. 
         [0013]    The technical objects to be achieved by the present invention are not limited to the above-mentioned objects and other technical objects that have not been mentioned above will become evident to those skilled in the art from the following description. 
         [0014]    To solve the problems, the present invention provides a temperature control method of a chemical vapor deposition device, including a chamber, a susceptor rotatably placed within the chamber and configured to have wafers loaded on its upper surface, a gas supplier provided within the chamber and configured to spray gas toward the wafers, heaters provided within the susceptor and configured to heat the wafers, and temperature sensors provided at the upper portion of the chamber and configured to measure a temperature at an upper surface of the susceptor, wherein the temperature control method includes the steps of (a) calculating a temperature distribution of the susceptor based on the measured values of the temperature sensors and classifying relatively high temperature sections of the temperature distribution as susceptor sections and relatively low temperature sections of the temperature distribution as wafer sections and (b) controlling the heaters by comparing a temperature at a position, selected from the susceptor sections or the wafer sections, with a preset reference temperature. 
         [0015]    Furthermore, in the step (a), the temperature distribution corresponds to a time-based temperature distribution, and the step (a) may include classifying the relatively high temperature sections of the time-based temperature distribution as the susceptor sections and the relatively low temperature sections of the time-based temperature distribution as the wafer sections by using a preset filtering function. 
         [0016]    Furthermore, the step (a) may include the steps of (a1) classifying the measured values of the temperature sensors into the relatively high temperature sections and the relatively low temperature sections by using a preset filtering function and (a2) matching a susceptor section in preset wafer arrangement angle information with the high temperature section and matching a wafer section in the preset wafer arrangement angle information with the low temperature section. 
         [0017]    Furthermore, the step (a) may further include the step of allocating an identifier ID to each of the susceptor sections and the wafer sections so that a specific section can be selected from among the susceptor sections and the wafer sections. 
         [0018]    Furthermore, the step (b) may include controlling the heaters based on a temperature of a section to which an identifier selected by a user has been allocated. 
         [0019]    Furthermore, the temperature control method may further include the step of excluding temperature change sections, appearing when temperature is changed at edge portions of the wafers, from the susceptor sections or the wafer sections. 
         [0020]    To solve the problems, the present invention provides a temperature control method of a chemical vapor deposition device, including a chamber, a susceptor rotatably placed within the chamber and configured to have wafers loaded on its upper surface, a gas supplier provided within the chamber and configured to spray gas toward the wafers, heaters provided within the susceptor and configured to heat the wafers, temperature sensors provided at the upper portion of the chamber and configured to measure a temperature at an upper surface of the susceptor, a motor configured to rotate the susceptor, and an encoder configured to measure the rotating speed of the motor, wherein the temperature control method includes the steps of (a) calculating a first temperature distribution of the susceptor by matching the measured values of the temperature sensors with the measured value of the encoder; (b) calculating a second temperature distribution of the susceptor by using the measured values of the temperature sensors and preset wafer arrangement angle information; (c) adjusting the measured value of the encoder if an error exists by comparing the first temperature distribution with the second temperature distribution; and (d) controlling the heaters based on a third temperature distribution calculated using the adjusted measured value of the encoder. 
         [0021]    Furthermore, the step (a) may include calculating a susceptor rotation angle by using a motor rotation angle, calculated using the measured value of the encoder, and a preset rotation ratio of the motor to the susceptor and calculating the first temperature distribution by matching the calculated susceptor rotation angle with the measured values of the temperature sensors. 
         [0022]    Furthermore, the step (a) may further include the step of classifying a relatively high temperature section of the first temperature distribution as a first susceptor section and a relatively low temperature section of the first temperature distribution as a first wafer section by using a preset filtering function. 
         [0023]    Furthermore, the step (b) may further include the step of classifying a relatively high temperature section of the second temperature distribution as a second susceptor section and a relatively low temperature section of the second temperature distribution as a second wafer section by using the preset filtering function. 
         [0024]    Furthermore, the step (b) may further include the steps of (b1) classifying the second temperature distribution into a relatively high temperature section and a relatively low temperature section by using the preset filtering function and (b2) matching a second susceptor section in the preset wafer arrangement angle information with the high temperature section and matching a second wafer section in the preset wafer arrangement angle information with the low temperature section. 
         [0025]    Furthermore, the step (b2) may include performing the matching so that an average variation between an angle of the center of the second susceptor section or the second wafer section and an angle of the center of the high temperature section or the low temperature section is minimized. 
         [0026]    Furthermore, the step (b2) may include performing the matching so that an average variation between an angle of the boundary of the second susceptor section or the second wafer section and an angle of the boundary of the high temperature section or the low temperature section is minimized. 
         [0027]    Furthermore, the temperature control method may further include the step of excluding temperature change sections, appearing when temperature is changed at the edge portions of the wafers, from the first susceptor section, the first wafer section, the second susceptor section, and the second wafer section. 
         [0028]    Furthermore, the step (c) may include adjusting the measured value of the encoder if an error is greater than a preset value by comparing the first susceptor section with the second susceptor section or the first wafer section with the second wafer section. 
         [0029]    Furthermore, the step (c) may include comparing an angle of the center of the first susceptor section with an angle of the center of the second susceptor section and an angle of the center of the first wafer section with an angle of the center of the second wafer section. 
         [0030]    Furthermore, the temperature control method may further include the step of determining whether a position of the second susceptor section or the second wafer section is approximately checked within a preset error range before the step (c), wherein if, as a result of the determination, the position of the second susceptor section or the second wafer section is approximately checked, the step (c) is performed. 
         [0031]    Furthermore, the step (c) may include adding or subtracting a numerical value, corresponding to the error, to or from an initial value of the measured value of the encoder for every preset time or whenever the error reaches a preset limit, if the error exists. 
         [0032]    Furthermore, the third temperature distribution of the step (d) may include a third susceptor section or a third wafer section calculated by using the adjusted measured value of the encoder, and the step (d) may include controlling the heaters by comparing an average temperature or a real-time temperature at a position, selected from the third susceptor section or the third wafer section, with a preset reference temperature. 
         [0033]    Furthermore, the step (d) may further include the step of allocating an identifier ID to each of the third susceptor section and the third wafer section so that a specific section can be selected from the third susceptor section and the third wafer section in the third temperature distribution. 
         [0034]    Furthermore, the step (d) may include controlling the heaters based on a temperature of a section to which an identifier selected by a user has been allocated. 
         [0035]    To solve the problems, the present invention provides a temperature control method of a chemical vapor deposition device, including a chamber, a susceptor rotatably placed within the chamber and configured to have wafers loaded on its upper surface surface, a gas supplier provided within the chamber and configured to spray gas toward the wafers, heaters provided within the susceptor and configured to heat the wafers, temperature sensors provided at the upper portion of the chamber and configured to measure a temperature at the upper portion of the susceptor, a motor configured to rotate the susceptor, an encoder configured to measure the rotating speed of the motor, a rotation recognition mark provided to be integrally rotated along with the susceptor, and a rotation recognition sensor provided at the chamber in order to determine a rotation state of the susceptor and configured to detect the rotation recognition mark, wherein the temperature control method includes the steps of (a) calculating a first temperature distribution of the susceptor by matching the measured values of the temperature sensors with the measured value of the encoder; (b) calculating a second temperature distribution of the susceptor by using the rotation recognition sensor and the temperature sensors; (c) adjusting the measured value of the encoder if an error exists by comparing the first temperature distribution with the second temperature distribution; and (d) controlling the heaters based on a third temperature distribution calculated using the adjusted measured value of the encoder. 
         [0036]    Furthermore, the step (b) may include the steps of (b1) calculating the rotation angle or rotation time of the susceptor by using the rotation recognition sensor and (b2) calculating the second temperature distribution by matching the calculated rotation angle or rotation time with the measured values of the temperature sensors. 
         [0037]    There is an advantage in that a temperature distribution can be accurately checked by using values measured by the temperature sensors without an additional complicated apparatus. 
         [0038]    Furthermore, there is an advantage in that reliability of values measured by the temperature sensors can be improved by using a value measured by the encoder which is chiefly embedded in the motor for rotating the susceptor. 
         [0039]    Furthermore, there is an advantage in that a temperature distribution can be accurately checked because an actual degree of a susceptor section or a wafer section selected through an allocated identifier can be checked. 
         [0040]    The technical effects of the present invention are not limited to the above-described effects and other technical effects that have not been described will be evidently understood by those skilled in the art from the following description. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0041]      FIG. 1  is a schematic cross-sectional view showing a chemical vapor deposition device according to a first embodiment of the present invention. 
           [0042]      FIG. 2  is a schematic cross-sectional view showing a chemical vapor deposition device according to a second embodiment of the present invention. 
           [0043]      FIG. 3  is a schematic cross-sectional view showing a chemical vapor deposition device according to a third embodiment of the present invention. 
           [0044]      FIG. 4  is an enlarged view of a rotation recognition mark and a rotation recognition sensor part. 
           [0045]      FIG. 5  is a schematic flowchart illustrating a first embodiment of a temperature control method of the chemical vapor deposition device according to the present invention. 
           [0046]      FIG. 6  is a graph illustrating an example of measured values of temperature sensors according to a lapse of time. 
           [0047]      FIG. 7  is a detailed flowchart illustrating the first embodiment of the temperature control method of the chemical vapor deposition device according to the present invention. 
           [0048]      FIG. 8  is a graph illustrating a process in which a high temperature section and a low temperature section are matched with a susceptor section or a wafer section based on preset wafer arrangement angle information. 
           [0049]      FIG. 9  is a flowchart illustrating a second embodiment of a temperature control method of the chemical vapor deposition device according to the present invention. 
           [0050]      FIG. 10  is a detailed flowchart illustrating an example of a method of calculating a first temperature distribution in  FIG. 9 . 
           [0051]      FIG. 11  is a detailed flowchart illustrating a process of calculating a third temperature distribution in the second embodiment of the temperature control method of the chemical vapor deposition device according to the present invention. 
           [0052]      FIG. 12  is a graph of an encoder signal showing the step of adjusting the encoder signal in the second embodiment of the temperature control method of the chemical vapor deposition device according to the present invention. 
           [0053]      FIG. 13  is a flowchart illustrating the temperature control method of the chemical vapor deposition device shown in  FIG. 2  or  FIG. 3 . 
       
    
    
     DETAILED DESCRIPTION OF THE EMBODIMENTS 
       [0054]    Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the disclosed embodiments, but may be implemented in various forms. The present embodiments are provided to complete the disclosure of the present invention and to allow those having ordinary skill in the art to understand the scope of the present invention. The shapes, etc., of elements in the drawings may be exaggerated in order to highlight clearer descriptions thereof. The same reference numbers are used throughout the drawings to refer to the same parts 
         [0055]      FIG. 1  is a schematic cross-sectional view showing a chemical vapor deposition device according to a first embodiment of the present invention. 
         [0056]    As shown in  FIG. 1 , the chemical vapor deposition device according to the present embodiment includes a chamber  10 , a susceptor  40 , a gas supplier  30 , heaters  50   a  and  50   b,  temperature sensors  20   a  and  20   b,  a motor  82 , a heater controller  71 , a temperature sensor controller  73 , a main controller  74 , and an encoder controller  75 . 
         [0057]    If the present embodiment is applied to a metal organic chemical vapor deposition (MOCVD) device, group III gas and group V gas may be sprayed from the gas supplier  30  toward wafers loaded into respective wafer pockets  41  at the tops of the susceptor  40 . 
         [0058]    The temperature sensors  20   a  and  20   b  may be provided on the upper portion of the chamber  10  in order to detect a temperature at an upper surface of the susceptor  40 . Alternatively, if temperature of the wafers loaded on the susceptor can be properly measured, the temperature sensors may be placed on the side of the susceptor or at the bottom of the susceptor. 
         [0059]    A pyrometer using reflected light from an object may be used as the temperature sensors  20   a  and  20   b  in order to measure temperature in a contactless way. For example, a pyrometer for measuring a surface temperature in the frequency of  700  Hz may be used. 
         [0060]    Since the gas supplier  30  is provided between the temperature sensors  20   a  and  20   b  and the susceptor  40 , through holes  31  may be provided within the gas supplier so that reflected light at the top of the susceptor  40  can be secured. 
         [0061]    A plurality of the temperature sensors  20   a  and  20   b  may be arranged in a radius direction to the rotating shaft  42  of the susceptor  40 . Accordingly, a temperature distribution according to the distance from the rotating shaft  42  of the susceptor  40  can be checked. 
         [0062]    The wafers are loaded into the respective wafer pockets  41  so that thin films can be formed on their top surfaces. 
         [0063]    A plurality of the wafer pockets  41  may be provided on the top surface of the susceptor  40 . 
         [0064]    A plurality of the heaters  50   a  and  50   b  each a doughnut form may be provided within the susceptor  40  in order to heat the susceptor  40 . The heater controller  71  may control the plurality of heaters  50   a  and  50   b  individually. That is, the heater controller  71  may uniformly control the temperatures of the plurality of heaters  50   a  and  50   b,  proportionally control the temperatures of the heaters  50   a  and  50   b,  and separately control a rise and fall of the temperatures of the heaters  50   a  and  50   b.    
         [0065]    The susceptor  40  is rotated around the rotating shaft  42  at high speed, but the heaters  50   a  and  50   b  may remain stopped. 
         [0066]    The motor  82  for rotating the susceptor  40  is provided. Rotary power of the motor is transferred to the rotating shaft  42  of the susceptor  40  through a belt  81 . The motor  82  is provided with an encoder (not shown) for measuring the rotating speed. 
         [0067]    If the rotary power is indirectly transferred through the belt  81 , there may be a slight difference between the rotation ratio and a design value. According to this difference, there may be a difference between a rotation angle of the susceptor, determined based on an encoder signal, and an actual rotation angle of the susceptor. 
         [0068]      FIG. 2  is a schematic cross-sectional view showing a chemical vapor deposition device according to a second embodiment of the present invention. The same reference numerals as those of  FIG. 1  are used to refer to similar elements  FIG. 1 , and a description of redundant parts is omitted for convenience of description. 
         [0069]    A rotation recognition mark  61   a  may be placed on the bottom of the susceptor  40 , and a rotation recognition sensor  62   a  for detecting the rotation recognition mark  61   a  may be provided outside the chamber  10 . The rotation recognition mark  61   a  is not limited to the above position, but may be placed in other parts to be integrally rotated along with the susceptor  40 . The rotation recognition mark  61   a  may include a concave part or a convex part, and the rotation recognition mark  61   a  may be formed of a reflection unit. Furthermore, the rotation recognition mark  61   a  is not limited to a specific form, and the rotation recognition mark  61   a  may have various forms or materials that can be detected by the rotation recognition sensor  62   a  according to the sensing method of the rotation recognition sensor  62   a.    
         [0070]    A method of detecting the rotation recognition mark may be various. For example, a method of checking whether light emitted from the rotation recognition sensor  62   a  has reached the rotation recognition mark  61   a  by checking that the light reaches the rotation recognition mark  61   a  through a transparent window  63  and light reflected from the rotation recognition mark  61   a  reaches the rotation recognition sensor  62   a  through the transparent window  63  may be used. That is, the above method is a method of detecting a change in a surface shape at the bottom of the susceptor  40 . 
         [0071]      FIG. 3  is a schematic cross-sectional view showing a chemical vapor deposition device according to a third embodiment of the present invention. 
         [0072]      FIG. 4  is an enlarged view of a rotation recognition mark and a rotation recognition sensor part. The same reference numerals as those of the second embodiment are used to refer to similar elements of the second embodiment, for convenience of description. 
         [0073]    As shown in  FIG. 3 , a rotation recognition sensor  62   b  may be placed near the rotating shaft  42  of the susceptor  40 . A ray of light L is emitted on one side of the rotation recognition sensor  62   b,  and the ray of light L is detected on the other side of the rotation recognition sensor  62   b.  A rotation recognition mark  61   b  may be placed in the rotating shaft  42  of the susceptor  40 . A moment when the rotation recognition mark  61   b  covers the ray of light L while passing through the rotation recognition sensor  62   b  can be detected by the rotation recognition sensor  62   b.    
         [0074]      FIG. 5  is a schematic flowchart illustrating a first embodiment of a temperature control method of the chemical vapor deposition device according to the present invention. 
         [0075]      FIG. 6  is a graph illustrating an example of measured values of temperature sensors according to a lapse of time. 
         [0076]    As can be seen from  FIG. 5 , first, a step S 101  of calculating a temperature distribution at the top of the susceptor by using values measured by the temperature sensors may be performed, and an example of which is shown in  FIG. 6 . 
         [0077]    As can be seen from  FIG. 6 , in general, temperatures in wafer sections W 1 , W 2 , W 3 , and W 4  are lower than temperatures in susceptor sections S 1 , S 2 , and S 3 . A temperature change section C in which temperature is not constant, but is changed may appear at the edge of the wafer. 
         [0078]    As can be seen from  FIG. 5 , next, a step S 103  of dividing the temperature distribution into high temperature sections and low temperature sections may be performed. In  FIG. 6 , a section having a relatively high temperature of 710° C. or higher is indicated by T 1 , and a section having a relatively low temperature of 710° C. or lower is indicated by T 2 . 
         [0079]    As can be seen from  FIG. 5 , next, a step S 105  of excluding the temperature change sections from the high temperature sections and the low temperature sections may be performed. Next, a step S 107  of assigning the high temperature sections as the susceptor sections and the low temperature sections as the wafer sections may be performed. As can be seen from  FIG. 6 , the sections W 1 , W 2 , W 3 , and W 4  from which the temperature change sections C have been excluded may be classified as the wafer sections, and the sections S 1 , S 2 , and S 3  from which the temperature change sections C have been excluded may be classified as the susceptor sections. 
         [0080]    As can be seen from  FIG. 5 , next, a step S 109  of selecting a target position for temperature control may be performed. Furthermore, a temperature at the target position may be compared with a reference temperature (S 111 ), and the heaters may be controlled based on the result of the comparison (S 113 ). As can be seen from  FIG. 6 , for example, a target position for temperature control may be selected from among the sections W 1 , W 2 , W 3 , W 4 , S 1 , S 2 , and S 3 , and the heaters may be controlled by comparing a preset reference temperature and temperature at the target position. 
         [0081]      FIG. 7  is a detailed flowchart illustrating the first embodiment of the temperature control method of the chemical vapor deposition device according to the present invention. 
         [0082]      FIG. 8  is a graph illustrating a process in which a high temperature section and a low temperature section are matched with a susceptor section or a wafer section based on preset wafer arrangement angle information. 
         [0083]    As can be seen from  FIG. 7 , first, a step S 201  of calculating a temperature distribution at the top of the susceptor may be performed (refer to  FIG. 6 ). Next, a step S 203  of dividing the temperature distribution into high temperature sections and low temperature sections using a filtering function may be performed. The filtering function may be designed to classify a section, having temperature higher than an average temperature of all the sections of the temperature distribution, as the high temperature section and a section having temperature lower than the average temperature of all the sections of the temperature distribution, as the low temperature section. Alternatively, the filtering function may be designed to classify a high temperature part of a specific temperature as the high temperature section and a low temperature part of the specific temperature as the low temperature section, if the specific temperature is repeatedly measured within a preset error range. 
         [0084]    Next, temperature change sections may be excluded from the high temperature sections and the low temperature sections (S 205 ). A step S 207  of matching a susceptor section with the high temperature section and a wafer section with the low temperature section by taking a preset wafer arrangement angle into consideration may be performed. Here, the step S 207  may be first performed, and the step S 205  may be then performed. 
         [0085]    The step S 205  may be performed in such a manner that a section in which the amount of an average temperature change during a preset time is greater than the amount of a preset temperature change is excluded from the high temperature sections and the low temperature sections. 
         [0086]    As can be seen from  FIG. 8 , there is shown a process of matching the susceptor sections and the wafer sections with the preset wafer arrangement angle. The matching method may be various, and an example of which is shown in  FIG. 8 . 
         [0087]    First, data included in the high temperature section and the low temperature section is prepared from values measured by the temperature sensors. Next, the arrangement angles of the wafer section and the susceptor section are brought close to the arrangement angles of the high temperature section and the low temperature section by rotating (moving an angle reference point in software) the preset wafer arrangement angle clockwise or counterclockwise at a specific angle on the basis of the rotating shaft of the susceptor. 
         [0088]    One of methods of bringing the arrangement angles of the wafer section and the susceptor section close to the arrangement angles of the high temperature section and the low temperature section is to minimize an average variation between an angle of a boundary of a second susceptor section or a second wafer section and an angle of a boundary of the high temperature section or the low temperature section. 
         [0089]    Alternatively, an average variation between an angle of the center of the second susceptor section or the second wafer section and an angle of the center of the high temperature section or the low temperature section may be minimized. 
         [0090]    As can be seen from  FIG. 7 , next, an identifier is allocated to each of the susceptor sections and the wafer sections (S 209 ), and a user selects a specific identifier ID (S 211 ). A step S 213  of comparing a temperature of the section to which the selected identifier has been allocated with a reference temperature may be performed. Accordingly, an actual temperature of the susceptor section (or the wafer section) can be checked through the allocated identifier. 
         [0091]    If, as a result of the comparison, the temperature of the section does not reach the reference temperature, the heaters may be controlled so that more electric power is supplied to the heaters. If, as a result of the comparison, the temperature of the section exceeds the reference temperature, the heaters may be controlled so that electric power supplied to the heaters is reduced (S 215 ). 
         [0092]      FIG. 9  is a flowchart illustrating a second embodiment of a temperature control method of the chemical vapor deposition device according to the present invention. 
         [0093]    The second embodiment corresponds to the case in which a step using a value measured by the encoder is further added in the first embodiment. 
         [0094]    As can be seen from  FIG. 9 , first, values measured by the temperature sensors are matched with a value measured by the encoder (S 301 ), and thus a first temperature distribution is calculated (S 303 ). 
         [0095]    Meanwhile, a second temperature distribution is calculated (S 307 ) by matching the measured values of the temperature sensors with preset wafer arrangement angle information (S 305 ). 
         [0096]    A step S 309  of checking whether there is an error by comparing the first temperature distribution with the second temperature distribution may be performed. 
         [0097]    If, as a result of the check, there is an error, a step S 311  of adjusting the measured value of the encoder in order to remove the error may be performed. 
         [0098]    Accordingly, a third temperature distribution in which the measured values of the temperature sensors have been matched with the adjusted measured value of the encoder is calculated (S 313 ). The heaters are controlled based on the third temperature distribution (S 315 ). 
         [0099]      FIG. 10  is a detailed flowchart illustrating an example of a method of calculating a first temperature distribution in  FIG. 9 . 
         [0100]    As can be seen from  FIG. 10 , a motor rotation angle per time may be calculated (S 301   b ) from a value measured by the encoder (the rotating speed of the motor) (S 301   a ). A susceptor rotation angle may be calculated (S 301   c ) by using a preset rotation ratio of the motor to the susceptor from the calculated motor rotation angle. A first temperature distribution for each angle may be calculated (S 303   a ) by matching the calculated susceptor rotation angle with values measured by the temperature sensors (S 301   d ). 
         [0101]      FIG. 11  is a detailed flowchart illustrating a process of calculating a third temperature distribution in the second embodiment of the temperature control method of the chemical vapor deposition device according to the present invention. 
         [0102]    As can be seen from  FIG. 11 , a first temperature distribution is calculated using a preset filtering function (S 401 ). A high temperature section is classified as a first susceptor section and a low temperature section is classified as a first wafer section in the calculated first temperature distribution (S 403 ). A step S 405  of excluding temperature change sections from the first susceptor section and the first wafer section is performed. A method of excluding the temperature change sections is similar to that of the first embodiment. 
         [0103]    Meanwhile, a second temperature distribution is calculated (S 407 ). A high temperature section is classified as a second susceptor section and a low temperature section is classified as a second wafer section in the calculated second temperature distribution (S 409 ). Temperature change sections are excluded from the second susceptor section and the second wafer section (S 411 ). 
         [0104]    Next, the second susceptor section may be matched with the high temperature section and the second wafer section may be matched with the low temperature section according to an angle on the basis of a preset wafer arrangement angle. A detailed matching method is similar to that of the step S 207 . 
         [0105]    Next, a step of allocating an identifier ID to each of the second susceptor section and the second wafer section may be further performed. 
         [0106]    Next, a step of checking whether a time (or angle) error exists (S 415 ) by comparing the center of the first susceptor section with the center of the second susceptor section or comparing the center of the first wafer section with the center of the second wafer section (S 413 ) may be performed. 
         [0107]    If, as a result of the check, the time (or angle) error exists, a value measured by the encoder may be adjusted (S 417 ), and a step S 419  of calculating a third temperature distribution may be performed. 
         [0108]      FIG. 12  is a graph of an encoder signal showing the step of adjusting the encoder signal in the second embodiment of the temperature control method of the chemical vapor deposition device according to the present invention. 
         [0109]    Before a step of adjusting an encoder signal is performed, a step of determining whether the position of the second susceptor section or the second wafer section is approximately checked within a preset error range may be performed. If, as a result of the determination, the position of the second susceptor section or the second wafer section is approximately checked, the step of adjusting the encoder signal may be performed. 
         [0110]    Whether the rotating speed of the susceptor is constant may be checked by using a value measured by the encoder. 
         [0111]    As can be seen from  FIG. 12 , if a first cycle T 1  measured by the encoder becomes long by ΔT 1 , the initial value of a second cycle T 2  is adjusted so that the second cycle T 2  is started at a point (T 1 -ΔT 1 ). Likewise, if the second cycle T 2  measured by the encoder becomes long by ΔT 2 , the initial value of the third cycle T 3  is adjusted so that the third cycle T 3  is started at a point (T 1 −ΔT 1 +T 2 −ΔT 2 ). 
         [0112]    The step S 417  of  FIG. 11  may be performed by adding or subtracting an error to or from the initial value of the value measured by the encoder every preset time or every time when the error reaches a preset limit, if there is the error by comparing the first temperature distribution with the second temperature distribution. 
         [0113]    As can be seen from  FIG. 11 , the third temperature distribution at step S 419  includes a third susceptor section or a third wafer section calculated by using the adjusted measured value of the encoder. The step S 315  of  FIG. 9  may be performed in such as way as to control the heaters by comparing an average temperature or a real-time temperature at a position, selected from the third susceptor section and the third wafer section, with a preset reference temperature. 
         [0114]    Furthermore, the step S 315  of  FIG. 9  may be performed in such a way as to control the heaters on the basis of a temperature of a section to which an identifier selected by a user has been allocated. 
         [0115]      FIG. 13  is a flowchart illustrating the temperature control method of the chemical vapor deposition device shown in  FIG. 2  or  FIG. 3 . The same reference numerals are used to refer to similar steps, for convenience of description. 
         [0116]    As can be seen from  FIG. 13 , the second temperature distribution may be calculated (S 307 ) by using the rotation recognition mark and the rotation recognition sensor (S 305   a ). 
         [0117]    If the rotation recognition mark and the rotation recognition sensor are used, an actual susceptor rotation state can be checked more reliably. Accordingly, an error between an actual susceptor rotation state and a susceptor rotation state checked using the encoder can also be accurately checked. Accordingly, the value of the encoder can also be accurately corrected. 
         [0118]    An embodiment of the present invention described above and shown in the drawings should not be interpreted as limiting the technical spirit of the present invention. The scope of the present invention is restricted by only the writing of the claims, and a person having ordinary skill in the art to which the present invention pertains may modify and change the technical spirit of the present invention in various forms. Accordingly, the modification and change may fall within the scope of the present invention as long as they are evident to those skilled in the art.