Patent Document

BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to an active X-ray sensing circuit and the sensing method thereof, more particularly to an active X-ray sensing circuit compensates and senses in one scan and the sensing method thereof. 
     2. Description of the Prior Art 
     The conventional X-ray sensing circuit and the X-ray sensing method are used for dealing with the threshold voltage compensation, lighting and reading etc. The compensation circuit and the reading circuit cannot be used at the same time. Thus, the compensation circuit and the reading circuit need independent circuit, therefore the above-mentioned circuit design becomes more complicated and huge. 
     At present, most active X-ray sensing circuit array (APS) focuses on the change of the sensing circuit. The circuit with threshold voltage compensation is scarcely available. Thus, it is unable to compensate the effect of device by the change of the threshold voltage. 
     In addition, the conventional technique is unable to compensate the threshold voltage and read the current at the same time. It will take longer time, and the leakage current of transistor will reduce the sensing accuracy. 
     In view of the above-mentioned consideration, in order to satisfy the long-term need of industry, it is necessary to provide an active X-ray sensing circuit and the X-ray sensing method. In the method, one-row pixel circuit compensates the threshold voltage and the next-row pixel circuit reads at the same time, so that the sensing circuit array can compensate and sense the threshold voltage in one scan to avoid the effect of the sensing accuracy and increase the sensing accuracy. 
     SUMMARY OF THE INVENTION 
     One purpose of the present invention is to provide an active X-ray sensing circuit and the sensing method thereof, it is applied to X-ray panel. The X-ray sensing circuit comprises two row of pixel circuit, and the two row of pixel circuit shares one scan line, and each data line connects with two switches. It is compensated the threshold voltage when it switches to the current source. It operates reading when it switches to amplifier. By applying specific scan line signal, the last-row pixel circuit is compensated and the next-row pixel row is read at the same time, so that the sensing circuit array can compensate and sense in one scan to avoid the effect of the leakage current. 
     One purpose of the present invention is to provide an active X-ray sensing circuit for compensating and sensing the threshold voltage of transistor in one scan. The active X-ray sensing circuit comprises a first-row pixel circuit, a second-row pixel circuit, a first data line, a second data line, a third data line and a fourth data line. The first-row pixel circuit comprises a first pixel circuit and a second pixel circuit, wherein, the first pixel circuit and the second pixel circuit are connected between the first scan line and the second scan line. The second-row pixel circuit comprises a third pixel circuit and a fourth pixel circuit, wherein, the third pixel circuit and the fourth pixel circuit are connected between the second scan line and the third scan line. 
     The first data line is connected to the first current source and the first amplifier. The second data line is connected to the second current source and the second amplifier. Wherein, the first pixel circuit and the third pixel circuit are connected between the first data line and the second data line. The third data line is connected to the second current source and the second amplifier. The fourth data line is connected to the third current source and the third amplifier. The second pixel circuit and the fourth pixel circuit are connected between the third data line and the fourth data line. Wherein, the first-row pixel circuit conducts the reading first. When the reading is completed by the first-row pixel circuit, the second-row pixel circuit conducts the reading. Meantime, the first pixel circuit and the second pixel circuit of the first-row pixel circuit compensate the threshold voltage, separately. 
     Another purpose of the present invention is to provide an X-ray sensing method for compensating and sensing the threshold voltage of transistor in one scan. The steps of the active X-ray sensing method comprises providing a first-row pixel circuit, which comprises a first pixel circuit and a second pixel circuit, wherein, the first pixel circuit and the second pixel circuit are connected between the first scan line and the second scan line. Providing a second-row pixel circuit, the second-row pixel circuit comprises the third pixel circuit and the fourth pixel circuit. Wherein, the third pixel circuit and the fourth pixel circuit are connected between the second scan line and the third scan line. Providing the first data line, the first data line is connected to the first current source and the first amplifier. Providing the second data line, the second data line is connected to the second current source and the second amplifier. Wherein, the first pixel circuit and the third pixel circuit are connected between the first data line and the second data line. 
     Then, providing the third data line, which is connected to the second current source and the second current source, providing the fourth data line, which is connected to the third current source and the third amplifier, wherein, the second pixel circuit and the fourth pixel circuit are connected between the second data line and the third data line. Wherein, the first-row pixel circuit, the second-row pixel circuit, the first data line, the second data line, the third data line and the fourth data line are set in the active X-ray sensing circuit. The first-row pixel circuit conducts the reading first. When the reading is completed by the first-row pixel circuit, the second-row pixel circuit conducts the reading. Meantime, the first pixel circuit and the second pixel circuit of the first-row pixel circuit compensate the threshold voltage separately. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same becomes better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein: 
         FIG. 1  is a diagram illustrating an embodiment for the active X-ray sensing circuit of the present invention; and 
         FIG. 2  is a diagram illustrating the flow chart of the active X-ray sensing circuit. 
     
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The preferred embodiments and the efficacy are described with the attached Figures as follows. Please referring to  FIG. 1 , which is a diagram illustrating an embodiment for the active X-ray sensing circuit of the present invention. The active X-ray sensing circuit  100  provided by the present invention comprises a first-row pixel circuit  110 , a second-row pixel circuit  112 , a first data line  120 , a second data line  122 , a third data line  124  and a fourth data line  126 . The first-row pixel circuit  110  comprises a first pixel circuit  102  and a second pixel circuit  104 . The first pixel circuit  102  and the second pixel circuit  104  are connected between the first scan line  130  and the second scan line  132 . The second-row pixel circuit  112  comprises a third pixel circuit  106  and a fourth pixel circuit  108 . Wherein, the third pixel circuit  106  and the fourth pixel circuit  108  are connected between the second scan line  132  and the third scan line  134 . 
     In this embodiment, the first data line  120  is connected to the first current source I 1  and the first amplifier A 1 . The second data line  122  is connected to the second current source I 2  and the second amplifier A 2 . Wherein, the first pixel circuit  102  and the third pixel circuit  106  are connected between the first data line  120  and the second data line  122 . The third data line  124  is connected to the second current source I 2  and the second amplifier A 2 . The fourth data line  126  is connected to the third current source I 3  and the third amplifier A 3 . Wherein, the second pixel circuit  104  and the fourth pixel circuit  108  are connected between the third data line  124  and the fourth data line  126 . The first-row pixel circuit  110  conducts the reading firstly. When the reading is completed by the first-row pixel circuit  110 , the second-row pixel circuit  112  conducts the reading. Meantime, the first pixel circuit  102  and the second pixel circuit  104  of the first-row pixel circuit  110  compensate the threshold voltage, separately. 
     As shown in  FIG. 1 , the first pixel circuit  102  comprises a first transistor T 1 , a first gate transistor T 1   g , a first source transistor T 1   s , a first capacitance transistor T 1   c , a first capacitor Cst 1  and a first diode D 1 . The first end of the first transistor T 1  is connected to the first scan line  130 . The third end of the first gate transistor T 1   g  is connected to the second end of the first transistor T 1 . The first end of the first gate transistor T 1   g  is connected to the first scan line  130 . The second end of the first gate transistor T 1   g  is connected to the second scan line  132 . The first end of the first source transistor T 1   s  is connected to the first data line  120 . The second end of the first source transistor T 1   s  is connected to the first scan line  130 . The third end of the first source transistor T 1   s  is connected to the third end of the first transistor T 1 . The first end of the first capacitance transistor T 1   c  is connected to the third end of the first gate transistor T 1   g . The second end of the first capacitance transistor T 1   c  is connected to the first scan line  130 . One end of the first capacitor is connected to the third end of the first capacitance transistor T 1   c . Another end of the first capacitor Cst 1  is connected to the third end of the first transistor T 1 . The first diode D 1  is connected to the third end of the first capacitance transistor T 1   c.    
     As shown in  FIG. 1 , the second pixel circuit  104  comprises a second transistor T 2 , a second gate transistor T 2   g , a second source transistor T 2   s , a second capacitance transistor T 2   c , a second capacitor Cst 2  and a second diode D 2 . The first end of the second transistor T 2  is connected to the first scan line  130 . The third end of the second gate transistor T 1   g  is connected to the second end of the second transistor T 2 . The first end of the second gate transistor T 2   g  is connected to the first scan line  130 . The second end of the second gate transistor T 2   g  is connected to the second scan line  132 . The first end of the second source transistor T 2   g  is connected to the third data line  124 . The second end of the second source transistor T 2   s  is connected to the first scan line  130 . The third end of the second source transistor T 2   s  is connected to the third end of the second transistor T 2 . The first end of the second capacitance transistor T 2   c  is connected to the third end of the second gate transistor T 2   g . The second end of the second capacitance transistor T 2   c  is connected to the first scan line  130 . One end of the second capacitor is connected to the third end of the second capacitance transistor T 2   c . Another end of the second capacitor Cst 2  is connected to the third end of the second transistor T 2 . The second diode D 2  is connected to the third end of the second capacitance transistor T 2   c.    
     As shown in  FIG. 1 , the third pixel circuit  106  includes a third transistor T 3 , a third gate transistor T 3   g , a third source transistor T 3   s , a third capacitance transistor T 3   c , a third capacitor Cst 3  and a third diode D 3 . The first end of the third transistor T 3  is connected to the second scan line  132 . 
     As shown in  FIG. 1 , the third end of the third gate transistor T 3   g  is connected to the second end of the third transistor T 3 . The first end of the third gate transistor T 3   g  is connected to the second scan line  132 . The second end of the third gate transistor T 3   g  is connected to the third scan line  134 . The first end of the third source transistor T 3   s  is connected to the second data line  132 . The second end of the third source transistor T 3   s  is connected to the second scan line  132 . The third end of the third source transistor T 3   s  is connected to the third end of the third transistor T 3 . The first end of the third capacitance transistor T 3   c  is connected to the third end of the third gate transistor T 3   g . The second end of the third capacitance transistor T 3   c  is connected to the second scan line  132 . One end of the third capacitor Cst 3  is connected to the third end of the third capacitance transistor T 3   c . Another end of the third capacitor Cst 3  is connected to the third end of the third transistor. The third diode is connected to the third end of the third capacitance transistor T 3   c.    
     As shown in  FIG. 1 , the fourth pixel circuit  108  comprises a fourth transistor T 4 , a fourth gate transistor T 4   g , a fourth source transistor T 4   s , a fourth capacitance transistor T 4   c , a fourth capacitor Cst 4  and a fourth diode D 4 . The first end of the fourth transistor T 4  is connected to the second scan line  132 . The third end of the fourth gate transistor T 4  is connected to the second end of the fourth transistor T 4 . The first end of the fourth gate transistor T 4   g  is connected to the second scan line  132 . The second end of the fourth gate transistor T 4   g  is connected to the third scan line  134 . The first end of the fourth source transistor T 4   s  is connected to the fourth data line  126 . The second end of the fourth source transistor T 4   s  is connected to the second scan line  132 . The third end of the fourth source transistor T 4   s  is connected to the third end of the fourth transistor T 4 . The first end of the fourth capacitance transistor T 4   c  is connected to the third end of the fourth gate transistor T 4   g . The second end of the fourth capacitance transistor T 4   c  is connected to the third scan line  134 . One end of the fourth capacitor is connected to the third end of the fourth capacitance transistor T 4   c . Another end of the fourth capacitor Cst 4  is connected to the third end of the fourth transistor T 4 . The fourth diode D 4  is connected to the third end of the fourth capacitance transistor T 4   c.    
     As shown in  FIG. 1 , the active X-ray sensing circuit  100  comprises a first current source I 1 , a first amplifier A 1 , a first amplifying capacitor CA 1 , a first switch SW 1  and a second switch SW 2 . The first switch SW 1  is connected between the first data line  120  and the first current source I 1 . The second switch SW 2  is connected between the first data line  120  and the first amplifier A 1 . The first amplifier A 1  is connected to the first amplifying capacitor CA 1 . 
     As shown in  FIG. 1 , the active X-ray sensing circuit  100  comprises a second current source I 2 , a second amplifier A 2 , a second amplifying capacitor CA 2 , a third switch SW 3  and a fifth switch SW 5 . The third switch SW 3  is connected between the second data line  122  and the second current source I 2 . The fifth switch SW 5  is connected between the second data line  122  and the second amplifier A 2 . The second amplifier A 2  is connected to the second amplifying capacitor CA 2 . 
     As shown in  FIG. 1 , the active X-ray sensing circuit  100  comprises a fourth switch SW 4  and a sixth switch SW 6 . The fourth switch SW 4  is connected between the third data line  124  and the second current source I 2 . The sixth switch SW 6  is connected between the third data line  124  and the second amplifier A 2 . The second amplifier A 2  is connected to the second amplifying capacitor CA 2 . 
     As shown in  FIG. 1 , the active X-ray sensing circuit  100  comprises a seventh switch SW 7  and an eighth switch SW 8 . The seventh switch SW 7  is connected between the fourth data line  126  and the third current source I 3 . The eighth switch SW 8  is connected between the fourth data line  126  and the third amplifier A 3 . The third amplifier A 3  is connected to the third amplifying capacitor CA 3 . 
     As shown in  FIG. 1 , after the active X-ray sensing circuit  100  is radiated by the X-ray, the scan line starts to provide the waveform of voltage. At time sequence  1 , the second switch SW 2  and the sixth switch SW 6  are turned off to control the first-row pixel circuit  110  for reading. The first voltage is changed because the first capacitor Cst 1  is radiated by the first X-ray, so that the first transistor T 1  outputs a corresponding first sensing current (not shown in the Figure). The second voltage is changed because the second capacitor Cst 2  is radiated by the second X-ray, so that the second transistor T 2  outputs a corresponding second sensing current (not shown in the Figure). 
     As shown in  FIG. 1 , at time sequence  2 , the second switch SW 2  and the sixth switch SW 6  are turned on, and the first switch SW 1  and the fourth switch SW 4  are turned off. The first-row pixel circuit  110  starts to conduct the compensation action. The first current flowing through the first transistor T 1  equals to the current value of the first current source I 1 . The first current source I 1  makes a first threshold voltage Vth 1  of the first transistor T 1  to be stored in the first capacitor Cst 1 , so that the first transistor Cst 1  conducts the compensation action. The second current flowing through the second transistor T 2  equals to the current value of the second current source I 2 . The second current source I 2  makes a second threshold voltage Vth 2  of the second transistor T 2  to be stored in the second capacitor Cst 2 , so that the second transistor Cst 2  conducts the compensation action. The fifth switch SW 5  and the eighth switch SW 8  are turned off. The second-row pixel circuit  112  conducts the compensation action. The third voltage is changed because the third capacitor Cst 3  is radiated by the third X-ray, so that the third transistor T 3  outputs a corresponding third sensing current (not shown in the Figure). The fourth voltage is changed because the fourth capacitor Cst 4  is radiated by the fourth X-ray, so that the fourth transistor T 4  outputs a corresponding fourth sensing current (not shown in the Figure). 
     As shown in  FIG. 1 , at time sequence  3 , the first switch SW 1  and the fourth switch SW 4  are turned on. The compensation action of the first-row pixel circuit  110  is finished. The third switch SW 3  and the seventh switch SW 7  are turned off. The second-row pixel circuit  112  starts to conduct the compensation action. The third current flowing through the third transistor T 3  equals to the current value of the second current source I 2 . The second current source I 2  makes a third threshold voltage Vth 3  of the third transistor T 3  to be stored in the third capacitor Cst 3 , so that the third transistor Cst 3  conducts the compensation action. The fourth current flowing through the fourth transistor T 4  equals to the current value of the third current source I 3 . The third current source I 3  makes a fourth threshold voltage Vth 4  of the fourth transistor T 4  to be stored in the fourth capacitor Cst 4 , so that the fourth transistor Cst 4  conducts the compensation action. 
     As shown in  FIG. 1 , at time sequence  4 , the third switch SW 3  and the seventh switch SW 7  are turned on. The compensation action of the second-row pixel circuit  112  is finished. 
     Please referring to  FIG. 2 , which is a diagram illustrating the flow chart of the active X-ray sensing circuit. Please referring to  FIG. 1  and  FIG. 2 , the X-ray sensing method is to provide an active X-ray sensing circuit for compensating and sensing the threshold voltage of transistor in one scan. 
     As shown in Step S 202 , a first-row pixel circuit  110  and a second-row pixel circuit  112  are provided. 
     As shown in Step S 204 , a first data line  120 , a second data line  122 , a third data line  124  and a fourth data line  126  are provided. The first-row pixel circuit comprises a first pixel circuit  102  and a second pixel circuit  104 . The first pixel circuit  102  and the second pixel circuit  104  are connected between the first scan line  130  and the second scan line  132 . The second-row pixel circuit  112  comprises a third pixel circuit  106  and a fourth pixel circuit  108 . Wherein, the third pixel circuit  106  and the fourth pixel circuit  108  are connected between the second scan line  132  and the third scan line  134 . 
     As shown in Step S 206 , after the active X-ray sensing circuit  100  is radiated by the X-ray, the scan line starts to provide the waveform of voltage. At time sequence  1 , the second switch SW 2  and the sixth switch SW 6  are turned off to control the first-row pixel circuit  110  for reading. The first voltage is changed because the first capacitor Cst 1  is radiated by the first X-ray, so that the first transistor T 1  outputs a corresponding first sensing current (not shown in the Figure). The second voltage is changed because the second capacitor Cst 2  is radiated by the second X-ray, so that the second transistor T 2  outputs a corresponding second sensing current (not shown in the Figure). 
     As shown in Step S 208 , at time sequence  2 , the second switch SW 2  and the sixth switch SW 6  are turned on, and the first switch SW 1  and the fourth switch SW 4  are turned off. The first-row pixel circuit  110  starts to conduct the compensation action. The first current flowing through the first transistor T 1  equals to the current value of the first current source I 1 . The first current source I 1  makes a first threshold voltage Vth 1  of the first transistor T 1  to be stored in the first capacitor Cst 1 , so that the first transistor Cst 1  conducts the compensation action. The second current flowing through the second transistor T 2  equals to the current value of the second current source I 2 . The second current source I 2  makes a second threshold voltage Vth 2  of the second transistor T 2  to be stored in the second capacitor Cst 2 , so that the second transistor Cst 2  conducts the compensation action. The fifth switch SW 5  and the eighth switch SW 8  are turned off. The second-row pixel circuit  112  conducts the compensation action. The third voltage is changed because the third capacitor Cst 3  is radiated by the third X-ray, so that the third transistor T 3  outputs a corresponding third sensing current (not shown in the Figure). The fourth voltage is changed because the fourth capacitor Cst 4  is radiated by the fourth X-ray, so that the fourth transistor T 4  outputs a corresponding fourth sensing current (not shown in the Figure). 
     As shown in Step S 210 , at time sequence  3 , the first switch SW 1  and the fourth switch SW 4  are turned on. The compensation action of the first-row pixel circuit  110  is finished. The third switch SW 3  and the seventh switch SW 7  are turned off. The second-row pixel circuit  112  starts to conduct the compensation action. The third current flowing through the third transistor T 3  equals to the current value of the second current source I 2 . The second current source I 2  makes a third threshold voltage Vth 3  of the third transistor T 3  to be stored in the third capacitor Cst 3 , so that the third transistor Cst 3  conducts the compensation action. The fourth current flowing through the fourth transistor T 4  equals to the current value of the third current source I 3 . The third current source I 3  makes a fourth threshold voltage Vth 4  of the fourth transistor T 4  to be stored in the fourth capacitor Cst 4 , so that the fourth transistor Cst 4  conducts the compensation action. 
     As shown in Step S 212 , at time sequence  4 , the third switch SW 3  and the seventh switch SW 7  are turned on. The compensation action of the second-row pixel circuit  112  is finished. Therefore, all steps are finished. 
     It is understood that various other modifications will be apparent to and can be readily made by those skilled in the art without departing from the scope and spirit of this invention. Accordingly, it is not intended that the scope of the claims appended hereto be limited to the description as set forth herein, but rather that the claims be construed as encompassing all the features of patentable novelty that reside in the present invention, including all features that would be treated as equivalents thereof by those skilled in the art to which this invention pertains.

Technology Category: 5