Abstract:
A charging circuit detects a battery voltage Vp and a charging voltage of a main condenser. When a charge of the condenser is instructed, if the battery voltage is smaller than prescribed value Vpo, the charge is performed in a single control mode. And then, when the charging voltage of the main condenser is larger than a prescribed value Vco, the mode is changed to a push-pull control mode from the single control mode. When the charge of the condenser is instructed, if the battery voltage is larger than prescribed value Vpo, the charge is performed in a push-poll control mode independent of the charging voltage.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention pertains to a charging circuit that performs charging of a prescribed load and to equipment accompanying this charging circuit, said charging circuit being used, for example, in a flash light device, a camera with a built-in flash, a measuring device using flash light, or a battery charger. 
     2. Description of the Related Art 
     The circuit shown in FIG. 12 is one example of a conventional charging circuit, and is used as a charging circuit for a built-in flash in a camera. This circuit comprises step-up transformer  100 , power supply battery  101 , main condenser  102  for flash light emission, FET (field effect transistor)  103  and diode  104 . FET  103  is placed in series with primary coil L 1  of step-up transformer  100 , and pulse signals having a certain frequency are input from drive control circuit  105  to gate G of said FET  103 . The periodic turning ON and OFF of FET  103  periodically turns ON and OFF the application of primary voltage El to primary coil L 1  of step-up transformer  100  such that AC (alternating current) secondary voltage Vf is applied to secondary coil L 2 . 
     AC secondary current I 2  output by means of the secondary voltage Vf is rectified by diode  104  and supplied to main condenser  102  such that main condenser  102  is intermittently charged. When charging voltage Vh of main condenser  102  has reached a prescribed final level, the output of said pulse signals by drive control circuit  105  is stopped and the charging operation comes to an end. 
     In the charging circuit described above, where one battery is shared for the charging circuit and for the operation of the camera main unit, if a sudden step-up of voltage is made to take place in a condition where the battery has been consumed and its voltage is relatively low, the battery voltage will suddenly decrease, which may cause problems in the supply of power to other circuits of the camera. Even if the battery is not shared between the charging circuit and the camera main unit, if load is applied suddenly in a condition in which the battery has been consumed, the battery voltage will decrease suddenly, which may cause a problem with the charging circuit itself. Conversely, if charging is performed slowly so that the load is light, charging must be performed over a long period of time. 
     SUMMARY OF THE INVENTION 
     The object of the present invention is to provide a charging circuit in which the charging time may be reduced and in which a sudden decrease in battery voltage during charging may be prevented, such that problems in the operation of circuits may be prevented. 
     Another object of the present invention is to provide equipment accompanying the charging circuit in which no problem occurs in the power supply to circuits other than the charging circuit due to a sudden decrease in battery voltage during charging. 
     Yet another object of the present invention is to provide equipment accompanying the charging circuit in which the charging time may be reduced and problems in the operation of the equipment due to a sudden decrease in battery voltage during charging may be prevented. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     These and other objects and features of this invention will become clear from the following description, taken in conjunction with the preferred embodiments with reference to the accompanied drawings, in which: 
     FIG. 1 shows the appearance of a camera with a built-in flash, which comprise the first embodiment of the present invention; 
     FIG. 2 is a circuit diagram showing a flash charging circuit in the first embodiment of the present invention; 
     FIG. 3 a  is a waveform chart showing the pulse signals that are input to the gates of switch elements during single control in the first embodiment; 
     FIG. 3 b  is a waveform chart showing pulse signals that are input to the gates of switch elements during push-pull control in the first embodiment; 
     FIG. 4 is an illustration to explain the relationships among the battery voltage, charging voltage and control method in the first embodiment. 
     FIG. 5 is a waveform chart showing pulse signals that are input to the gates of switch elements when the control is switched from single control to push-pull control in the first embodiment; 
     FIG. 6 is an illustration showing the changes in the charging voltage of a condenser over time in the first embodiment. 
     FIG. 7 is an illustration showing the changes in the battery voltage over time in the first embodiment; 
     FIG. 8 is a flow chart showing the control of the charging by a controller in the first embodiment; 
     FIG. 9 is a circuit diagram showing a flash charging circuit in a second embodiment of the present invention; 
     FIG. 10 is a flow chart showing the control of the charging by a controller in the second embodiment; 
     FIG. 11 a  is a waveform chart showing pulse signals that are output to the gates when the battery voltage is high in a third embodiment of the present invention; 
     FIG. 11 b  is a waveform chart showing pulse signals that are output to the gates when the battery voltage is low in the third embodiment; and 
     FIG. 12 is a circuit diagram showing one example of a conventional flash charging circuit; 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     A flash device and a camera with a built-in flash are shown as examples of the charging circuit of the present invention and accompanying equipment in this description. However, the present invention may be used in other equipment in which flash light is used, such as measuring devices and battery chargers. 
     The first embodiment of the present invention is explained with reference to FIGS. 1 through 8. FIG. 1 shows the appearance of a camera with a built-in flash, which comprise the first embodiment of the present invention. It is a camera of the type in which camera main unit  200  and the flash device are built as one integral unit, and has flash light emission window  201 . FIG. 2 shows a charging circuit for the flash device built into said camera. This flash charging circuit comprises step-up transformer  10 . Primary coil circuit C 1  and secondary coil circuit C 2  are connected to both ends of primary coil L 1  and both ends of secondary coil L 2  of said step-up transformer, respectively. Primary coil circuit C 1  has switch elements  12  and  14 , each comprising a MOS-type FET, on either end of primary coil L 1 , and the connection between switch elements  12  and  14  is grounded. Voltage (battery voltage) Vp is applied to the center of primary coil L 1  by battery  30 . 
     The power supply battery for the camera&#39;s controller  40  that controls the operations of the camera main unit of this embodiment, such as film winding/rewinding, lens drive, light measurement and exposure is used as the battery described above. For elements  12  and  14 , various semiconductor switch elements other than said MOS-type FETs, such as connection-type FETs and silicon transistors, may be used. 
     Secondary coil circuit C 2  has diode bridge circuit  16  comprising four diodes D 1  through D 4 , for example, as a full-wave rectifying means, and diode  18  and main condenser  20  to accumulate the charge for flash light emission are located between the output terminal of this diode bridge circuit  16  and the ground. The charge accumulated in main condenser  20  is provided to light emission circuit C 3  containing discharge tube  32  and trigger switch  33 . 
     Discharge tube  32  is placed just inside flash light emission window  201  as shown in FIG.  1 . When shutter release button  202  is operated after preparation for light emission is complete, a signal is sent to trigger switch  33 , whereby discharge tube  32  emits light and the exposure sequence simultaneously takes place. 
     Said battery voltage Vp and charging voltage Vc which comprises voltage between both ends of main condenser  20 , are input to controller  26 , a control means, via A/D converters  22  and  24 , respectively. This controller  26  comprises a CPU (central processing unit) or a CPU together with various circuits such as an oscillation circuit. By inputting pulse signals to gates G 1  and G 2  of FETs  12  and  14 , it drives FETs  12  and  14  ON and OFF and at the same time also performs the following control operations depending on said voltages Vp and Vc. 
     a) Where battery voltage Vp is smaller than prescribed value Vpo that is set in advance and charging voltage Vc is also smaller than prescribed value Vco: Here, as shown in FIG. 3 a , pulse signals are output to gate G 1  of FET  12  only so that only FET  12  is driven ON and OFF and FET  14  is kept OFF at all times. Naturally, a reverse operation in which FET  14  is driven ON and OFF while FET  12  is kept OFF at all times may also be used. Hereinafter the control method in which only one of the FETs is driven in this manner is called ‘single control’. 
     b) Where battery voltage Vp is equal to or larger than said prescribed value Vpo, or where charging voltage Vc is equal to or larger than said prescribed value Vco: Here, as shown in FIG. 3 b , pulse signals are output to gates G 1  and G 2  of FETs  12  and  14  with a mirror-image phase (in other words, when the signal for one FET is ON, the signal for the other FET is OFF) such that so-called ‘push-pull’ control is performed, in which FETs  12  and  14  are alternately driven ON and OFF. 
     The relationships among battery voltage Vp, charging voltage Vc and the single and push-pull control methods described above is shown in FIG.  4 . 
     The operation of this circuit will now be explained with reference to the flow chart in FIG.  8 . When an instruction to charge main condenser  20  to prepare for flash light emission is input, battery voltage Vp is detected (# 11 ) and is compared with prescribed value Vpo (# 13 ). Where the battery is only slightly consumed and battery voltage Vp is equal to or larger than prescribed value Vpo, controller  26  generates pulse series signals set to a prescribed frequency with a duty ratio of 50%, for example, in order to perform push-pull control in # 15 , and outputs the signals to gates G 1  and G 2  of FETs  12  and  14  while alternating the mirror-image phase. 
     In other words, while FET  12  is ON, FET  14  is OFF. Therefore, primary current i 1  flows from primary coil L 1  to FET  12  while this is occurring. As a result, secondary voltage that causes secondary current I 1  to flow from secondary coil L 2  to the connection between diodes D 1  and D 2  is applied to secondary coil L 2 , and said secondary current I 1  is input to main condenser  20  after being full-wave rectified by diode bridge circuit  16 . 
     On the other hand, while FET  12  is OFF, FET  14  is ON. Therefore, primary current i 2  flows from primary coil L 1  to FET  14  while this is occurring. As a result, secondary voltage that causes secondary current I 2  to flow from secondary coil L 2  to the connection between diodes D 3  and D 4  is applied to secondary coil L 2 , and said secondary current I 2  is input to main condenser  20  after being full-wave rectified by diode bridge circuit  16 . 
     Therefore, the alternate turning ON and OFF of FETs  12  and  14  alternately causes positive and negative secondary voltage to be applied to either end of secondary coil L 2 , and secondary currents I 1  and I 2  that are generated via this secondary voltage are full-wave rectified by diode bridge circuit  16  and continuously supplied to main condenser  20 . The continuous supply of these secondary currents I 1  and I 2  causes main condenser  20  to accumulate charge quickly and charging voltage Vc of main condenser  20  increases rapidly. This charging voltage Vc is detected by controller  26 , and when it has reached prescribed final voltage level Vc 1 , controller  26  determines that the charging has been completed, thereby stopping the output of pulse signals to FETs  12  and  14  and ending the charging operation (# 25 , # 27 ). 
     On the other hand, where the battery is substantially consumed and battery voltage Vp is smaller than prescribed value Vpo when said charge instruction is input (NO in # 13 ), there is a possibility that the supply of power to the camera&#39;s other circuits may be hindered due to a decrease in voltage caused by the charging. Therefore, push-pull control which entails a sudden load is not performed when the charging starts. The process advances to step # 17  where charging voltage Vc of the condenser is detected and it is determined whether or not charging voltage Vc is equal to or larger than prescribed value Vco (# 19 ). Since the charging voltage is low when the charging starts, the process advances to step # 23  where charging starts using single control. Controller  26  outputs pulse series signals set at a prescribed frequency with a duty ratio of 50% to one of the FETs. Here it outputs pulse signals to gate G 1  of FET  12  only. As a result, only FET  12  is driven ON and OFF while FET  14  is kept OFF. 
     Therefore, where only one of the FETs, namely FET  12 , is driven as described above, secondary voltage is caused to be applied to secondary coil L 2  during only the time that FET  12  is ON, and single control is performed in which charging of main condenser  20  takes place. Such single control slows down the charging speed in comparison with the push-pull control in which FETs  12  and  14  are alternately turned ON and OFF, and a charging operation takes place in which a sudden decrease in battery voltage Vp caused by a sudden step-up of voltage can be prevented. 
     When charging voltage Vc has reached or exceeded prescribed value Vco (# 17 , # 19 ), the process advances to step # 21  and the control is switched to push-pull control. The charging operation using push-pull control that started in step # 15  or step # 21  continues until charging voltage Vc reaches prescribed final voltage level Vc 1  (# 25 , # 27 ). 
     The relationship between changes in charging voltage Vc over time and the switching between single control and push-pull control is explained with reference to FIGS. 5 and 6. If it is assumed that the time when charging voltage Vc of main condenser  20  reaches prescribed value Vco (which is smaller than final voltage Vc 1 ) is t 0 , single control is used until time t 0  so that power supply to the charging circuit and the circuits of the camera main unit is not hindered due to a sudden decrease in the battery voltage. When charging voltage Vc has reached prescribed value Vco (at time t 0 ), charging is performed using push-pull control because the load decreases and a sudden decrease in battery voltage is less likely to occur. 
     First, FET  12  is driven ON and OFF using single control while FET  14  is kept OFF. While charging takes place slowly, when charging voltage Vc has reached prescribed voltage Vco which is smaller than said final voltage Vc 1  (see time t 0  in FIG.  6 ), or namely, when the charging load has been reduced substantially and a sudden decrease in battery voltage Vp is less likely to occur, controller  26  switches from single control to push-pull control, where it outputs pulse signals to both FETs  12  and  14  (see FIG. 5) and the charging speed of main condenser  20  increases. When charging voltage Vc has reached said final voltage Vc 1 , controller  26  stops the output of pulse signals and ends the charging operation. 
     As described above, in the circuit of this embodiment, where battery voltage Vp is smaller than prescribed value Vpo, or in other words, where a sudden decrease in battery voltage Vp is relatively likely to occur, single control is used, such that the total period of time in which both FETs  12  and  14  are ON is short. On the other hand, where battery voltage Vp is equal to or larger than prescribed value Vpo, or in other words, where a sudden decrease in battery voltage Vp is relatively less likely to occur, so-called push-pull control is used, such that the total period of time in which both FETs  12  and  14  are ON is long. Therefore, where battery voltage Vp is relatively high, charging takes place while the charging time is being reduced. On the other hand, where battery voltage Vp is relatively low, no sudden charging takes place, as a result of which a sudden decrease in battery voltage Vp is prevented, and therefore a failure in the supply of power to the camera&#39;s other circuits or to the charging circuit itself is prevented. 
     Furthermore, where battery voltage Vp is smaller than prescribed value Vpo, when charging voltage Vc of main condenser  20  becomes equal to or larger than prescribed value Vco, or in other words, when the charging load is relatively light, the control method is switched to said push-pull control so that the total period of time in which both FETs  12  and  14  are ON becomes long. By doing so, a sudden decrease in battery voltage may be prevented and at the same time the charging time may be further reduced. 
     FIG. 7 indicates by a solid line the changes in battery voltage Vp over time when single control is used in the period between when charging voltage Vc is 0 until time t 0  when it reaches prescribed value Vco (which is smaller than final voltage Vc 1 ) and push-pull control is used after said time t 0 . The changes in voltage from the start of charging when charging takes place using push-pull control is shown by a dotted line. As shown in this drawing, the battery voltage decreases significantly when charging begins, but by using single control during the period in which the load is large (until time t 0 ), the decrease in battery voltage Vp after the commencement of charging may be mitigated by DV relative to when push-pull control is used in the same period. 
     A second embodiment will now be explained with reference to FIG.  9 . In this embodiment, FET  14  shown in the first embodiment is omitted and a circuit construction in which single control where only FET  12  is driven ON and OFF is used at all times is used. Where battery voltage Vp is smaller than prescribed value Vpo, pulse signals having a relatively low duty ratio (33% for example) are output to gate G 1 , while where battery voltage Vp is equal to or larger than said prescribed value Vpo, pulse signals having a duty ratio higher than said duty ratio (50% for example) are output to gate G 1  by controller  26 . 
     By changing the period of time in which the FET is ON through switching among multiple types of pulse signals having different duty ratios, an effect in which the charging time is reduced while a decrease in battery voltage Vp is prevented may be obtained. Further, as in the first embodiment, even if battery voltage Vp is smaller than prescribed value Vpo, control takes place such that the pulse duty ratio is switched depending on whether or not the charging voltage is equal to or larger than the prescribed value through the detection of charging voltage Vc of main condenser  20 . If charging voltage Vc is smaller than the prescribed value, rapid charging is not performed in order to prevent a sudden decrease in the battery voltage. In other words, FET  12  is driven using pulse signals having a relatively low duty ratio (33% for example). When charging voltage Vc becomes equal to or larger than prescribed value Vco, pulse signals having a higher duty ratio than said duty ratio (50% for example) are switched to and charging is performed using said signals. 
     The control by the controller in the second embodiment is shown by the flow chart in FIG.  10 . An explanation will be provided regarding differences from the flow chart showing the control of the first embodiment (FIG.  8 ). In the second embodiment, drive using pulse signals having a low duty ratio is performed in the step in which single control was used in the first embodiment (# 63 ) so that a sudden decrease in battery voltage may be prevented. Regarding the steps in which push-pull control was used, drive using pulse signals with a high duty ratio (# 55 , # 61 ) is performed in the second embodiment so that the charging time may be reduced. 
     A third embodiment will now be explained with reference to FIGS. 11 a  and  11   b . The circuit construction of this embodiment is the same as that shown in FIG. 2, in which push-pull control where both FETs  12  and  14  are driven at all times is used. Where battery voltage Vp is equal to or larger than the prescribed value, the duty ratio of the pulse signals to gates G 1  and G 2  is set at a relatively large value (50% for example), as shown in FIG. 11 a , and where battery voltage Vp is smaller than the prescribed value, the duty ratio of pulse signals to gates G 1  and G 2  is set at a value smaller than said duty ratio (33% for example), as shown in FIG. 11 b . By this, the same effect obtained in the first and second embodiments may be obtained in this embodiment as well. 
     In addition, needless to say, in the third embodiment as well as in the first and second embodiments, a sudden decrease in the battery voltage may be prevented and the charging time may simultaneously be further reduced by having a higher duty ratio when charging voltage Vc is relatively high than when said voltage Vc is low. In this case, the duty ratio when battery voltage Vp is low and charging voltage Vc is high does not necessarily have to be identical to the duty ratio when battery voltage Vp is high. The duty ratio in this case need only be set to be larger than the duty ratio when both battery voltage Vp and charging voltage Vc are low. In terms of control by the controller, this embodiment differs from the second embodiment in that push-pull control is used, whereas signal control was used in the second embodiment, but the control may be performed using the same sequence for the control of the second embodiment shown in the flow chart in FIG.  10 . 
     While explanations of the embodiments above were provided referring to a camera with a built-in flash in which the flash device and camera main unit are made as a single integral unit, needless to say, the present invention may be applied in a mountable flash device that is separate from the camera main unit, as well as in charging circuits and accompanying devices such as measuring devices using flash light and battery chargers. 
     Obviously, many modifications and variations of the present invention are possible in light of the explanation provided above. It is therefore to be understood that within the scope of the appended claims, the invention may be applied other than as specifically described.