JP5755908B2 - Peripheral device, control method thereof, and USB cable - Google Patents

Description

  The present invention relates to a technique for supplying power from a host device to a peripheral device via a communication cable.

  The USB interface is used not only in personal computers (PCs) but also in various electrical devices such as peripheral devices and mobile phones. In the USB interface, not only data transmission / reception but also power can be supplied from the USB host controller to the USB device. That is, power can be supplied from the PC to the peripheral device. Such a power supply method is called USB bus power. At present, the USB 2.0 standard is the mainstream as a standard that peripheral devices using USB bus power as a power source comply with.

  The maximum current consumption that can be supplied by USB bus power in the USB 2.0 standard is 500 mA. That is, the current supplied to the load existing inside the peripheral device is limited to 500 mA. When the current supplied to the load inside the peripheral device is likely to exceed 500 mA, the current supplied to the load is controlled so as not to exceed the maximum current consumption. Since the peripheral device cannot obtain a necessary amount of current, the operation of the load stops halfway or the operation of the load becomes slow. If the user desires that the internal operation of the peripheral device is executed smoothly and the operation time is shortened, it is necessary to consider supplying a current exceeding 500 mA.

  According to Patent Document 1, as a method of supplying a current exceeding 500 mA, a method of supplying a double current by transmitting current in parallel to two USB ports of a peripheral device using two USB cables. Has been proposed. This method cannot be adopted in a peripheral device having only one USB port. Therefore, according to Patent Document 2, a method has been proposed in which a USB cable is inserted into each of two USB ports provided in the host device, and the two USB cables are bundled into one USB cable in the middle.

JP 2008-225993 A JP 2008-027114 A

  However, in the method of supplying current from the two USB ports on the host device side, it is necessary to use a plurality of USB ports of the host device or device. In particular, small PCs (notebook PCs, mobile PCs, etc.) not only have a smaller number of USB ports than desktop PCs, but users often want to use a plurality of USB ports for other purposes. Therefore, it is inconvenient for the user to use two PC USB ports for one peripheral device. If three or more USB ports are mounted on a small PC or the like, the cost will increase.

  Incidentally, in recent years, the USB 3.0 standard has been announced, and PCs and peripheral devices compatible with the USB 3.0 standard have been released. The maximum supply current of the host device corresponding to the USB 3.0 standard is 900 mA. Therefore, future peripheral devices can increase the amount of current supply by USB bus power by supporting the USB 3.0 standard.

  If the peripheral device is compatible with the USB 3.0 standard, the power supply amount can be increased without using a plurality of USB ports provided in the host device. However, in order to comply with the USB 3.0 standard, it is necessary to mount an IC corresponding to the USB 3.0 standard and a USB 3.0 standard connector on the peripheral device. Therefore, this also leads to an increase in the cost of the peripheral device. Furthermore, since the USB 3.0 standard increases the number of pins of the connector, a wider space is required than in the past, and it is difficult to mount a plurality of connectors on a small PC.

  Therefore, the present invention provides a technique that can improve the convenience for the user by improving the compatibility of the host device and the peripheral device with the cable connection. Specifically, while using a single cable for both the host device and the peripheral device, the increase in connector space due to current supply is suppressed, and the upper limit value in the standard that the peripheral device conforms to The current can be received beyond that. For example, in the present invention, the peripheral device can receive a current exceeding the upper limit of the USB 2.0 standard from the host device compatible with the USB 3.0 standard while adopting the USB connector corresponding to the USB 2.0 standard. The purpose is to.

According to the present invention, a USB interface unit that can be connected to a host device that supports the USB 3.0 standard by using either a USB cable that conforms to the USB 3.0 standard or a USB cable that conforms to the USB 2.0 standard; An energization condition changing unit that changes the current condition based on a voltage level of a connection terminal that is not used for data communication or current supply in the USB 2.0 standard among the connection terminals of the USB interface unit. peripheral device characterized by Ru with is provided.

Further, the present invention is a peripheral device having a load,
A USB interface unit that is connected to a host device via a single USB cable, transmits and receives data using the USB cable, and receives a current supplied by the host device;
A voltage detection unit that detects a voltage of a terminal that is not used for data transmission and reception among a plurality of terminals included in the USB interface unit and is not used for receiving the current;
If the voltage detected by the voltage detector is the first level, the upper limit value of the current supplied to the load is set to the first value, and if the voltage detected by the voltage detector is the second level, An upper limit setting unit that sets the upper limit of the current supplied to the load to the second value;
A current detector for detecting a current supplied to the load;
If the current detected by the current detection unit does not exceed the upper limit value set by the setting unit, the current supply to the load is continued, and the current detected by the current detection unit is set by the setting unit. If the upper limit is not exceeded, a current control unit that reduces the current supplied to the load;
It is characterized by providing.

  ADVANTAGE OF THE INVENTION According to this invention, the mutual compatibility accompanying the cable connection (especially USB cable connection) of a host apparatus and a peripheral device can be improved, and a user's convenience can be improved. More specifically, among a plurality of terminals included in a USB interface unit connected to a host device via a single USB cable, a terminal that is not used for data transmission and reception and is also not used for current reception If the detected voltage is the first level, the upper limit value of the current supplied to the load is set to the first value. If the detected voltage is the second level, the upper limit value of the current supplied to the load is set. Set the value to the second value. Therefore, in the present invention, while using a single USB cable for both the host device and the peripheral device, an increase in connector space due to current supply is suppressed, and the upper limit on the standard that the peripheral device conforms to The current can be received exceeding the value.

1 is a block diagram illustrating a schematic configuration of a scanner according to a first embodiment. It is a figure which shows the terminal of a USB cable. It is a figure which shows the terminal of a USB cable. It is a figure which shows the circuit of the current control part inside the scanner which concerns on the 1st-2nd Example. It is a flowchart which shows operation | movement of the scanner which concerns on 1st Example. It is a block diagram which shows schematic structure of the scanner which concerns on 2nd. It is a flowchart which shows operation | movement of the scanner which concerns on 2nd Example. It is sectional drawing which shows the structural example of an image reading apparatus. It is a top view which shows the structural example of an image reading apparatus. It is a perspective view which shows the conveyance drive system of an image reading apparatus. It is sectional drawing which shows the normal rotation conveyance in an image reading apparatus. It is sectional drawing which shows reverse conveyance in an image reading apparatus.

[Example 1]
FIG. 1 is a block diagram showing a schematic configuration of a scanner using USB bus power as a power source according to an embodiment of the present invention. As an embodiment of the present invention, the PC 1 is employed as a host device, and a scanner 8 (image reading device) is employed as a peripheral device having a load, and the present invention will be described. The peripheral device may be an image forming device or other device as long as it is a device having a USB interface.

  The PC 1 includes a socket-type USB connector 2 as a host-side connector. The shape of the USB connector 2 differs between the higher standard USB 3.0 and the lower standard USB 2.0. A plug-type connector attached to one end of the USB cable 3 is connected to the USB connector 2. A plug-type connector attached to the other end of the USB cable 3 is connected to a socket-type USB connector 6 provided in the scanner 8. The USB connector 6 is an example of an interface unit that is connected to a host device via a single cable, transmits and receives data using a single cable, and receives current supplied from the host device. The USB connector 6 is also an example of a USB interface unit that can be connected to a host device that is an external connection destination using any of a plurality of different types of USB cables. Inside the USB cable 3 are a signal line 4 for transmitting and receiving data and a power supply line 5 for supplying power by USB bus power. There is a limit to the upper limit of the current that can be supplied by USB bus power. The upper limit value of the USB 2.0 standard is 500 mA, while the upper limit value of the USB 3.0 standard is 900 mA. The current control unit 9 functions as a power supply unit that receives supply of current from the host device via the USB interface unit in accordance with the energization conditions with the host device that matches the terminal connection state between the USB interface unit and the USB cable. The current control unit 9 also serves as a power supply unit for driving the main body of the peripheral device.

  The current supplied via the USB cable 3 is supplied to the load 10 via the current control unit 9. The load 10 includes a device 11 having a relatively large load variation and a device 12 having a relatively small load variation. That is, the device 12 is an example of a first load having a small load variation compared to the second load, and the device 11 is an example of a second load having a large load variation compared to the first load. is there. The device 11 includes a motor 13 for conveying a document. The device 12 includes an LED 15 that is a light source for illuminating a document, an image reading sensor 17 such as a CIS or CCD, and an AFE (analog front end) 16 that converts an analog signal into a digital signal. To do.

  A scanning operation will be described. The motor 13 starts conveying the document. When the document passes over the sensor 17, the LED 15 emits light, and the document is exposed to light. The sensor 17 reads the reflected light from the document and outputs an analog signal corresponding to the amount of received light to the AFE 16. The analog signal output from the sensor 17 is converted into digital data by the AFE 16 and transmitted to the PC 1 via the CPU 14 and the signal line 4 of the USB cable 3. The CPU 14 controls the driving time and driving force of the motor 13 and the light emission time and light emission amount of the LED 15.

  The interface determination unit 7 determines whether the USB connector 6 is connected to the higher standard USB connector 2 or whether the USB connector 6 is connected to the lower standard USB connector 2 ′. For example, the interface determination unit 7 determines whether the PC 1 is a PC compatible with the USB 2.0 standard or a PC compatible with the USB 3.0 standard. The interface determination unit 7 transmits connection information indicating the determination result to the CPU 14. The CPU 14 sets an upper limit value of the current supplied to the load 10 of the scanner 8 in accordance with the connection information transmitted from the interface determination unit 7. For example, if the connection information indicates that the PC is connected to the USB 2.0 standard, the CPU 14 sets the upper limit value of the current supplied to the load 10 to 500 mA. On the other hand, if the connection information indicates that the PC is connected to the USB 3.0 standard, the CPU 14 sets the upper limit value of the current supplied to the load 10 to 900 mA.

  The current control unit 9 measures the current supplied to the load 10 of the scanner 8 and transmits measurement information indicating the measurement result to the CPU 14. The CPU 14 compares the measurement value calculated based on the measurement information from the interface determination unit 7 with the set upper limit value. If the measured value exceeds the upper limit value, the CPU 14 instructs the current control unit 9 to reduce the current supplied to the load 10 or to stop the current supply completely. On the other hand, if the measured value is below the upper limit value, the CPU 14 controls the current control unit 9 so as to continue supplying current to the load 10. That is, the CPU 14 functions as an energization condition changing unit that appropriately changes a supply current condition as an energization condition with the PC 1 in accordance with the terminal connection state of the USB cable 3 to the USB connector 6. Here, the terminal connection state of the USB cable 3 means that, for example, the connection between the USB cable 3 and the USB connector 6 is a connection state corresponding to the USB 3.0 standard or a connection state corresponding to the USB 2.0 standard. means. Note that the present invention is not limited to the USB connection specification, and an interface corresponding to data communication using a connection cable having different connection standard specifications (terminal specifications, etc.) between the host device and the peripheral device which are external connection destinations. Peripheral devices including a power supply condition changing unit that changes a power supply condition with the host device in accordance with a terminal connection state of each connection cable with respect to the interface unit are also widely targeted. As described above, in the present invention, the connection state is determined using the difference in the connection standards, and the energization conditions (data communication, current supply, etc.) are changed according to the determination result of the connection state. It is possible to improve the convenience for the user by improving the compatibility with the cable connection with the peripheral device.

  As described above, the load 10 includes the device 12 having a small load variation and the device 11 having a large load variation. For example, the torque to be output by the motor 13 varies greatly depending on the type of document. Therefore, the motor 13 is included in the device 11 having a large load fluctuation. Conversely, the load fluctuation of the CPU 14, LED 15, AFE 16 and sensor 17 is only about 1/10 of the load fluctuation of the motor 13. Therefore, these have less load fluctuation than the motor 13.

  As described above, the scanner 8 receives power from the PC 1 by the USB bus power, and performs a scanning operation while limiting the current to the load to be less than the upper limit value.

  FIG. 2A shows connection terminals of the USB cable 3, the USB connector 2 of the PC 1, and the USB connector 6 of the scanner 8 when the USB connector 2 of the PC 1 corresponds to the USB 3.0 standard.

  According to the pin arrangement shown in FIG. 2A, the first pin 1p is V bus. The second pin 2p is a USB 2.0 differential signal D-. The third pin 3p is a USB 2.0 differential signal D +. The fourth pin 4p is GND. The fifth pin 5p is a USB 3.0 signal transmission line (−). The 6th pin 6p is a USB 3.0 signal transmission line (+). The seventh pin 7p is GND (ground potential). The eighth pin 8p is a USB 3.0 signal receiving line (−). The ninth pin 9p is a USB 3.0 signal receiving line (+). The USB connector 2 on the PC 1 side of the USB cable 3 adopts the standard A corresponding to the USB 3.0 standard. The USB connector 6 on the scanner 8 side employs mini or micro B. As described above, of the connectors at both ends of the USB cable 3, the connector connected to the host device is a connector corresponding to the USB 3.0 standard, and the connector connected to the peripheral device is a mini-type connector of the USB 2.0 standard. Or it is a micro B type connector.

  In this embodiment, the 4th pin 4p of the mini or micro B is used as the USB detection port. The first pin 1p, the second pin 2p, the third pin 3p, the fourth pin 4p, and the seventh pin 7p on the PC 1 side of the USB cable 3 are the first pin 1p, the second pin 2p, and the third pin number on the scanner 8 side. It is wired so as to be connected to 3p, 5th pin 5p, 4th pin.

  FIG. 2B shows connection terminals of the USB cable 3, the USB connector 2 ′ of the PC 1, and the USB connector 6 of the scanner 8 when the USB connector 2 ′ of the PC 1 corresponds to the USB 2.0 standard. .

  According to the pin arrangement shown in FIG. 2B, the first pin 1p is V bus. The second pin 2p is a USB 2.0 differential signal D-. The third pin 3p is a USB 2.0 differential signal D +. Pins 2 and 3 are communication terminals. The fourth pin 4p is GND. The USB connector 2 'on the PC 1 side employs USB 2.0 standard A. The USB connector 6 and the USB cable 3 on the scanner 8 side are the same as in FIG.

  2A and 2B is that the 4th pin 4p of the USB connector 6 on the scanner 8 side is connected to the 7th pin 7p on the PC1 side. When the scanner 8 is connected to a host device compatible with USB 3.0, the 7th pin 7p on the host device side of the USB cable 3 becomes GND. On the other hand, when the scanner 8 is connected to a host device compatible with USB 2.0, the seventh pin 7p on the host device side of the USB cable 3 is opened. The 7th pin 7p on the host device side is connected to the 4th pin 4p on the peripheral device side. Therefore, the interface discriminating unit 7 can discriminate whether it is connected to the higher standard or the lower standard by the potential applied to the fourth pin 4p on the peripheral device side. Thus, the 4th pin 4p on the peripheral device side can be used as a USB detection port (detection terminal). That is, the terminal that the voltage detection unit detects the voltage is the 4th pin in the USB 2.0 standard, and the 4th pin is connected to the 7th pin of the connector corresponding to the USB 3.0 standard by the USB cable.

  As shown in FIGS. 3A and 3B, the 4th pin 4p of the USB connector 6 on the scanner 8 side is a data transfer signal terminal other than the 6th pin 6p on the PC1 side or 6p, and 5p, 8p, 9p. Even if it is connected to the same, a similar configuration can be adopted. At this time, when the PC 1 detects the connection with the peripheral device, a communication signal is transmitted to the device in order to check whether the peripheral device is compatible with the higher standard or the lower standard. Using this signal, the interface discriminating unit 7 can discriminate whether it is connected to the higher standard or the lower standard by the potential applied to the 4th pin 4p on the peripheral device side.

  FIG. 4 shows a circuit of a part related to the current control of the current control unit 9. As shown in FIG. 4, the interface determination unit 7 includes a pull-up resistor 33 and a detection port 34 of the CPU 14. The 4th pin 4p on the peripheral device side is pulled up by the pull-up resistor 33 and connected to the detection port 34 of the CPU 14. That is, the current control unit 9 includes a pull-up resistor 33 connected between the fourth pin and the reference voltage source. However, when the 4th pin is connected to the 6th pin 6p on the PC1 side or 5p, 8p, 9p which is a data transfer signal terminal other than 6p, the higher standard and the lower standard regardless of the presence or absence of the pull-up resistor 33 It is possible to determine which one is connected.

  When the PC 1 is a host device compatible with the USB 2.0 standard, the 4th pin of the USB connector 6 on the scanner 8 side is N.P. C. That is, the potential of the detection port 34 of the CPU 14 to which the fourth pin 4p on the scanner 8 side is connected becomes High (Vcc) by pull-up. On the other hand, when the PC 1 is a host device compatible with the USB 3.0 standard, the 4th pin of the USB connector 6 on the scanner 8 side is connected to GND. That is, the potential of the detection port 34 of the CPU 14 to which the fourth pin 4p on the scanner 8 side is connected is Low (zero V). As described above, the pull-up resistor 33 connected to the detection port 34 of the CPU 14 and the detection port of the CPU 14 function as the interface determination unit 7. As described above, the pull-up resistor 33 detects the voltage of the terminal (the fourth pin 4p) that is not used for data transmission and reception and is not used for current reception among the plurality of terminals included in the interface unit. Functions as a voltage detector.

  In addition, when the 4th pin 4p of the USB connector 6 on the scanner 8 side is connected to the 5th, 8p, or 9p data transfer signal terminals other than the 6th pin 6p on the PC1 side or 6p, only the detection port of the CPU 14 It functions as the interface determination unit 7.

  The CPU 14 sets the upper limit value of the amount of current supplied to the load 10 including the CPU 14 to 500 mA when the detection port 34 is High, and the upper limit value of the current supplied to the load 10 when the potential of the detection port 34 is Low. Set the value to 900 mA. Thus, if the voltage detected by the voltage detection unit is the first level, the CPU 14 sets the upper limit value of the current supplied to the load to the first value, and the voltage detected by the voltage detection unit is the second level. If so, it functions as an upper limit setting unit that sets the upper limit of the current supplied to the load to the second value.

  In the current control unit 9, a detection resistor 32 is inserted between a power supply line that supplies power to the CPU 14 and the load 10 and the first pin 1 p (V bus) of the USB connector 6. The detection resistor 32 converts a current supplied to the CPU 14 and the load 10 into a voltage. The current control unit 9 that functions as a current detection unit includes a detection resistor 32 that is a current / voltage conversion resistor inserted between the first pin and a load in the USB 2.0 standard.

  The measured value of the voltage measured by the detection resistor 32 is transmitted to the CPU 14. The CPU 14 calculates the current consumed by the entire scanner 8 from the measured value of the voltage. For example, the measurement value is converted into current consumption by multiplying the measurement value by a predetermined coefficient or by substituting the measurement value into a predetermined function. The detection resistor 32 functions as a current detection unit that detects a current supplied to the load.

  The CPU 14 compares the current consumption value of the load 10 with the set upper limit value. If the current consumption value of the load 10 is below the upper limit value, the CPU 14 sends a control signal so that the switch 31 is ON. If the current consumption value exceeds the upper limit value, the CPU 31 is OFF. A control signal is sent so that In other words, the CPU 14 continues to supply current to the load unless the current detected by the current detection unit exceeds the upper limit set by the setting unit, and the current detected by the current detection unit is set by the setting unit. If it does not exceed the upper limit, it functions as a current control unit that reduces the current supplied to the load.

  Here, as an extreme example, a configuration is adopted in which the supply of current to the load 10 is zero, but a configuration in which the current is reduced so that the current to the load 10 does not exceed the upper limit value may be adopted. Good. Thus, in this embodiment, it is determined whether or not the host device is compatible with the USB 3.0 standard, and the current supplied to the entire load of the peripheral device is controlled according to the determination result.

  FIG. 5 is a flowchart showing the control of this embodiment. In S <b> 501, the CPU 14 recognizes that the PC 1 and the scanner 8 are connected via the USB cable 3.

  In step S502, the CPU 14 uses the interface determination unit 7 to determine whether the PC 1 is a PC compatible with USB 2.0 or a PC compatible with USB 3.0. If PC1 is P corresponding to USB3.0, the process proceeds to S503. In S503, the CPU 14 sets the upper limit value of the current supplied to the load 10 to 900 mA. On the other hand, if PC1 is P corresponding to USB 2.0, the process proceeds to S504. In S504, the CPU 14 sets the upper limit value of the current supplied to the load 10 to 500 mA. As described above, when the potential at the connection point between the 4th pin and the pull-up resistor becomes low level, the CPU 14 sets the upper limit value to 900 mA, and when the potential at the connection point between the 4th pin and the pull-up resistor becomes high level. , And functions as an upper limit setting unit for setting the upper limit to 500 mA.

  In S <b> 505, the CPU 14 measures the current (current consumption) supplied to the load 10 using the current control unit 9 and determines whether or not the measured value of the current consumption exceeds the upper limit value. The current consumption varies depending on how much current the load 10 requires. When the measured value of the current consumption exceeds the upper limit value, the process proceeds to S506. In S506, the CPU 14 reduces the current supplied to the load 10. For example, the CPU 14 switches the switch 31 to stop the supply of current to the load 10. If the measured current consumption value does not exceed the upper limit value, the process proceeds to S507. In S507, the CPU 14 reduces the current supplied to the load 10. For example, the CPU 14 sends a control signal to the switch 31 so that the switch 31 continues to be ON.

  According to the present invention, of a plurality of terminals included in an interface unit connected to a host device via a single cable, a terminal that is not used for data transmission and reception and is not used for current reception. If the detected voltage is the first level, the upper limit value of the current supplied to the load is set to the first value. If the detected voltage is the second level, the upper limit value of the current supplied to the load is set. Is set to the second value. Therefore, in the present invention, while using a single cable for both the host device and the peripheral device, an increase in connector space due to current supply is suppressed, and the upper limit value according to the standard with which the peripheral device complies It becomes possible to receive the current exceeding.

  Specifically, according to the present embodiment, the interface determination unit 7 is used for data transmission and reception among a plurality of pins included in the USB connector 6 connected to the PC 1 via a single USB cable 3. In addition, the voltage of the 4th pin that is not used for receiving current is detected. The CPU 14 sets the upper limit value of the current supplied to the load 10 to 500 mA if the detected voltage is high level, and sets the upper limit value of the current supplied to the load 10 to 900 mA if the voltage is low level. . Therefore, the scanner 8 does not use a plurality of USB cables and is not equipped with a USB 3.0 standard connector, and from the PC 1 corresponding to the USB 3.0 standard, the upper limit value of 500 mA of the USB 2.0 standard is obtained. It will be possible to receive an excess current. That is, in the first embodiment, the upper limit value of the current supplied to the load of the peripheral device is set without using a plurality of USB ports of the host device or the peripheral device and without making the peripheral device compliant with the USB 3.0 standard. Can be increased.

[Example 2]
The second embodiment is a case where the scanner 8 can receive power not only from USB bus power but also from an external power source such as an AC adapter. The parts common to the first embodiment are assigned the same reference numerals to simplify the description.

  FIG. 6 is a block diagram illustrating a schematic configuration of a scanner that is driven by USB bus power and power from an external power source according to the first embodiment. The AC adapter 20 is an example of an external power source. The external power source may be a rechargeable power source.

  The scanner 8 includes a power connector 22, and a power cable 21 from the AC adapter 20 is connected to the power connector 22. Therefore, the scanner 8 can be supplied with power from the USB bus power and the AC adapter 20. As described above, the power connector 22 functions as an external power supply connection knowledge unit that receives a current supplied from an external power supply different from that of the host device. The switches 25 and 26 are switches that are switched ON and OFF according to a switching signal from the power supply control unit 24.

  The external power supply detection unit 23 detects whether the AC adapter 20 is connected to the power supply connector 22 and transmits the detection result to the power supply control unit 24. For example, the external power supply detection unit 23 detects whether or not the AC adapter 20 is connected to the power connector 22 according to whether the potential between two terminals of the power connector 22 is high level or low level, for example. The external power supply detection unit 23 functions as an external power supply detection unit that detects whether or not an external power supply is connected to the external power supply connection unit.

  The power supply control unit 24 switches the switches 25 and 26 based on the detection result output from the external power supply detection unit 23 to change the power supply path of the power supplied to the load 10. For example, when the external power source detection unit 23 detects that the AC adapter 20 is connected to the power connector 22, the power source control unit 24 outputs a switching signal for turning off the switch 25 and a switching signal for turning on the switch 26. To do. As a result, the power supply path is changed so that power is supplied to the device 11 having a large load fluctuation by the USB bus power and power is supplied from the AC adapter 20 to the device 12 having a small load fluctuation. As described above, when the external power source detection unit detects that the external power source is connected to the external power source connection unit, the power source control unit 24 and the switches 25 and 26 use the current supplied from the external power source as the first of the loads. The current supply system is switched so that the current supplied from the host device is supplied to the second load among the loads, and the external power supply detection unit is not connected to the external power supply connection unit. When this is detected, it functions as a switching unit that switches the current supply system so that the current supplied from the host device is supplied to the first load and the second load.

  When the external power detection unit 23 detects that the AC adapter 20 is not connected to the power connector 22, the power control unit 24 outputs a switching signal for turning on the switch 25 and outputs a switching signal for turning off the switch 26. Output. As a result, the power supply path is changed so that all of the power supplied to the load 10 is supplied by the USB bus power.

  FIG. 7 is a flowchart illustrating the control according to the second embodiment. In step S <b> 701, the external power detection unit 23 determines whether the AC adapter 20 is connected to the power connector 22. If the AC adapter 20 is connected to the power connector 22, the process proceeds to S702. In step S <b> 702, the power control unit 24 turns off the switch 25 and turns on the switch 26. As a result, the power supply path is switched so that the power supplied from the PC 1 by the USB bus power is supplied to the device 11 having a large load fluctuation, and the power supplied from the AC adapter 20 is supplied to the device 12 having a small load fluctuation.

  On the other hand, if the AC adapter 20 is not connected to the power connector 22, the process proceeds to S703. In step S <b> 703, the power supply control unit 24 turns on the switch 25 and turns off the switch 26. As a result, the power supply path is switched so that the power supplied from the PC 1 by the USB bus power is supplied to the device 11 having a large load variation and the device 12 having a small load variation.

  The subsequent operation is as described with reference to FIG. However, if an external power source is connected to the scanner 8, the USB bus power can concentrate on supplying power to the device 11 with a large load fluctuation, and therefore the possibility that the current due to the USB bus power exceeds the upper limit value is reduced. It will be.

  According to this embodiment, a peripheral device capable of receiving power from an external power source and USB bus power is provided. If an external power supply is not connected to the peripheral device, the USB bus power supplies power to the device 11 having a large load variation and the device 12 having a small load variation. On the other hand, if an external power supply is connected to the peripheral device, the USB bus power can be dedicated to supplying power to the device 11 having a large load fluctuation. Further, as described in the first embodiment, the scanner 8 can receive the current at the upper limit value corresponding to the USB 3.0 standard even if the scanner 8 does not support the USB 3.0 standard. Therefore, in the second embodiment, the possibility that the current due to the USB bus power exceeds the upper limit value is reduced as compared with the first embodiment. That is, in the second embodiment, the upper limit value of the current supplied to the load of the peripheral device is set without using a plurality of USB ports of the host device or the peripheral device and without making the peripheral device compliant with the USB 3.0 standard. It can be further increased.

  In the above embodiment, the description has been made on the assumption that the connector on the peripheral device side is a USB 2.0 standard connector, but it may be a USB 3.0 standard connector. If the connector on the peripheral device side is a USB 3.0 standard connector, the user may misunderstand that the peripheral device itself can communicate with the USB 3.0 standard, but this is not a problem. Let's go.

  Making the peripheral device side connector a USB 3.0 standard connector means that the plug of the USB cable 3 and the peripheral device side socket become the USB 3.0 standard. Since the USB 3.0 standard connector group has backward compatibility with the USB 2.0 standard, the present invention can be applied. In other words, the fourth pin of the plug (second connector) of the USB cable 3 and the fourth pin of the socket on the peripheral device side may be set as voltage detection target pins. This is because the fourth pin is a pin that is not used for communication or current reception among the pins included in the second connector. The 4th pin of the plug on the peripheral device side of the USB cable 3 is connected to any one of the 5th to 9th pins of the plug (first connector) on the host device side. In addition, although the pin after the 6th pin is unnecessary among the pins with which the socket of the peripheral device side is provided, these pins may be open | released and may be used for another use.

<Configuration of image reading apparatus>
Below, with reference to FIG.8 and FIG.9, the structural example of the scanner apparatus 8 which concerns on this invention is demonstrated. The motor described above is used to drive various rollers of the scanner 8.

  As shown in FIG. 8, the scanner 8 includes a mounting table 81, a paper feed unit 82, a separation unit 101, a paper feed roller (an example of a paper feed unit) 102, a retracting unit 112, a transport path 83, a transport unit 84, and image reading. Section 85, paper discharge section 86, detection sensor (first detection means) 89, and discharge sensor (second detection means) 100. The image reading unit 85 is the sensor 17 described above, and includes, for example, a first image reading unit 51 and a second image reading unit 52.

  A sheet medium S to be read is placed on the placement table 81. The sheet feeding unit 82 separates the plurality of sheet media S one by one by the separation unit 101, and feeds the sheet medium to the conveyance unit 84 by the sheet feeding roller 102. A bent portion 111 is formed in the conveyance path 83 through which the sheet medium S is conveyed. Such a bent portion 111 is formed to reduce the size of the scanner 8. That is, in order to form the conveyance path 83 without providing the bent portion 111, it is necessary to enlarge the apparatus. The sheet medium having relatively low rigidity is deformed along the bent portion 111 and is conveyed. In addition, the conveyance path 83 is provided with a retracting section 112 that is a part of the conveyance path 83 extending from the paper discharge section 86 beyond the conveyance section 84 and into which the leading edge of the sheet can enter. Note that, as in the present embodiment, the retracting portion 112 may have an end portion opened on the back surface of the apparatus main body, or may be provided only inside the apparatus main body without opening outside the apparatus.

  The transport unit 84 includes a first transport roller pair 41. The paper discharge unit 86 includes a second conveyance roller pair 61 and discharges the sheet medium S sent from the conveyance unit 84 to the outside of the apparatus. In addition, the scanner 8 includes a drive unit (not shown) that rotates the first and second transport roller pairs 41 and 61 in the forward / reverse direction.

  The first image reading unit 51 and the second image reading unit 52 are provided between the first conveyance roller pair 41 and the second conveyance roller pair 61, and the image of the first surface of the document passing therethrough and the first image reading unit. It is possible to read an image on the second surface which is the back surface of the first surface. The detection sensor 89 is provided between the image reading unit 85 and the first conveying roller pair 41 and detects the presence or absence of a sheet medium passing therethrough. The discharge sensor 100 is provided in the vicinity of the paper discharge unit 86 and detects the presence or absence of a passing sheet medium. According to the scanner 8 according to the present embodiment, sheets can be fed from each of the paper feeding unit 82 and the paper ejection unit 86. When a sheet is fed from the paper discharge unit 86, the user inserts the sheet into the apparatus through an opening near the paper discharge unit 86.

  As shown in FIG. 9, the scanner 8 according to the present embodiment has an opening 96 formed in the back of the conveyance / reading unit 93, and the sheet medium M is linearly read when the image of the sheet medium M is read. The sheet medium M is temporarily protruded from the opening 96. This contributes to making the scanner 8 compact. For example, in this embodiment, the length dimension D in the depth direction of the scanner 8 is substantially equal to the length dimension D ′ in the longitudinal direction of the sheet medium M. Further, the sheet medium M conveyance path is a retreating portion (a conveyance path dedicated to the sheet medium M) that opens to the bent portion 111 from the discharge port 92 through a part of the sheet medium M conveyance path. It consists of a straight path formed in communication with the evacuation area 112 for switchback. In this embodiment, for example, the retracting unit 112 is opened as an opening 96 on the back (back) of the image reading apparatus A. The method for conveying the sheet medium M will be described in detail in the second conveying method described later.

<Conveyance drive configuration>
Next, the conveyance drive configuration of the scanner 8 will be described with reference to FIG. Reference numeral 121 shown in FIG. 10 denotes a driving unit for rotating the first and second transport roller pairs 41 and 61 in the forward / reverse direction. Reference numeral 122 denotes a drive gear fixed coaxially with the drive unit 121. Reference numeral 123 denotes a roller pair rotation detection unit that detects the rotation direction and the rotation speed of the drive unit 121.

  Reference numeral 71 denotes a first transport gear connected to the drive gear 122 via a gear train. A first drive roller 42 is fixed to the first transport gear 71 on the same axis. Therefore, the first conveying roller pair 41 including the first driving roller 42 and the first driven roller 43 that rotates by contacting the first driving roller 42 is connected to the first conveying gear 71.

  Reference numeral 72 denotes a second transport gear connected to the drive gear 122 via a gear train. A second drive roller 62 is fixed to the second transport gear 72 on the same axis. Therefore, the second conveying roller pair 61 including the second driving roller 62 and the second driven roller 63 that rotates by contacting the second driving roller 62 is connected to the second conveying gear 72. Reference numeral 73 denotes a connecting gear that connects the first transport gear 71 and the second transport gear 72.

  Note that the configuration shown in the present embodiment is an example and is not limited to this. For example, a configuration in which the number of gears constituting the gear train is different or a configuration in which the gear train is connected by a timing belt can be applied to the present invention. Further, the roller pair rotation detection unit 123 can detect any element as long as it is an element that is rotated by the drive unit 121.

  For example, the scanner 8 according to the present embodiment is provided with one drive unit 121 including a DC motor (drive motor). The driving force of the driving unit 121 is transmitted as rotational driving to the paper feed roller 102, the first driving roller 42, and the second conveying roller pair 61, which are an example of a driving system, through the gears 71, 72, and 73. Is done. That is, the drive unit 121 of the scanner 8 drives the paper feed roller 102, the first drive roller 42, and the second transport roller pair 61 under the same drive conditions. In the present embodiment, an example in which the drive unit is configured by one motor has been described. However, each roller may be driven separately by a plurality of motors, but a sheet feeding unit, a conveying unit, and a sheet discharging unit may be used. It is also possible to control each of them under simultaneous driving conditions.

<First transport method>
The scanner 8 according to the present embodiment can read a document by two types of document conveyance methods described below. First, the operation of the scanner 8 in the first transport method will be described with reference to FIG. The first transport method is a transport method in which a document (sheet medium S) is fed from the mounting table 81 and the document is discharged out of the apparatus from the paper discharge unit 86 via the transport path 83. As shown in FIG. 9, in the first conveying method, the plurality of first conveying roller pairs 41 and 41 ′ and the plurality of second conveying roller pairs 61 and 61 ′ rotate, whereby the sheet medium S is rotated. Transport.

  First, the user places a sheet bundle as a document on the placement table 81. Then, an instruction to start reading is received from the user via a reading control unit (not shown). The reading control unit is, for example, an operation unit provided in the scanner 8 or a computer connected to the scanner 8 via a network.

  When receiving the reading start instruction, the scanner 8 starts conveying the document by the first conveying method. When the conveyance of the original is started, the sheet medium S placed on the placement table 81 is conveyed into the apparatus by the normal rotation conveyance shown in FIG. Specifically, the sheet bundle is separated and conveyed one by one by the sheet feeding unit 82, is sent to the first conveying roller pair 41 through the bending portion 111, and is sent to the image reading unit 85 by the first conveying roller pair 41. Sent. At this time, the detection sensor 89 detects the timing when the leading edge of the sheet medium S reaches the image reading unit 85, and starts image reading. Then, after the image reading is finished, the paper is sequentially discharged out of the apparatus from the paper discharge unit 86 through the second conveyance roller pair 61 driven in the forward rotation direction.

<Second transport method>
Next, the operation of the scanner 8 in the second transport method will be described with reference to FIGS. In the second transport method, the sheet medium M is fed from the paper discharge unit 86, and the sheet medium M is transported toward the retracting unit 112 by each roller being driven in reverse rotation, and then each roller is driven forward. In this way, the sheet is conveyed again toward the paper discharge unit 86 and is discharged from the paper discharge unit 86. In the second transport method, for example, a card having relatively high rigidity can be used as the document (sheet medium M). In the following description, it is assumed that a card is used as a document (sheet medium M). The present invention is not limited to this, and an arbitrary sheet medium may be selected as a document. Also, as shown in FIG. 9, in the second conveying method, unlike the first conveying roller, only the first conveying roller pair 41 ′ and the second conveying roller pair 61 ′ rotate, thereby rotating the sheet medium. Transport M. That is, only the necessary roller pair is driven according to the width of the sheet medium M in the short direction. However, the present invention is not limited to this, and a plurality of roller pairs may be used also in the second transport method.

  First, when the ejection sensor 100 detects that a card has been inserted, the scanner 8 starts conveying a document by the second conveying method. As shown in FIG. 12, the card is driven reversely and is sent to the image reading unit 85 by the second conveying roller pair 61 that rotates in the reverse direction. Then, one side of the image is read, and the first conveying roller Sent to pair 41. Next, the leading edge of the card sent to the first conveying roller pair 41 is sent to the retracting portion 112 while avoiding the bent portion 111. As shown in FIG. 8, the evacuation unit 112 is located on a straight line connecting the paper discharge unit 86 and the conveyance unit 84, and avoids the bent portion 111 located between the paper supply unit 82 and the conveyance unit 84. Provided. By providing the retracting unit 112, it is possible to prevent the apparatus conveyance path from becoming long and the apparatus from becoming large. Furthermore, if the retracting portion 112 penetrates to the rear of the device, the retracting portion 112 itself can be made smaller, which is desirable for further downsizing the device.

  Thereafter, when the detection sensor 89 detects that the rear end of the card has passed the image reading unit 85, the first and second transport roller pairs 41 and 61 are rotated forward by the drive unit 121 as shown in FIG. Driven, the card transport direction is changed to the normal rotation direction, that is, the paper discharge unit 86 direction. Thereafter, when the card passes through the image reading unit 85 again, the other side is read, and the card is discharged from the paper discharge unit 86 to the outside of the apparatus again.

  In the above-described process, when the thickness of the card conveyed from the paper discharge unit 86 is relatively large, the load on the motor is increased compared to the case of a medium having a small thickness such as paper. As the motor load increases, the power consumption increases accordingly, and the power that can be supplied to image reading decreases. Therefore, in this configuration in which the card passes twice on the forward and backward paths of the card, the instantaneous maximum power consumption in the apparatus is reduced by separately reading the front / back images on the forward and backward paths. Can do. This is effective when power is supplied from an I / F such as a USB as described above.

  Here, with reference to FIG. 9, the 2nd conveyance method in the scanner 8 which aimed at size reduction which concerns on this embodiment is demonstrated in detail. As shown in FIG. 9, in the scanner 8, after the card is introduced from the discharge port 92, the entire card is temporarily accommodated in the scanner 8 in a state where the leading end of the card reaches the rear end of the scanner 8. The Thereafter, when the rear end portion of the card passes the detection sensor 89, the card enters the retracting portion 112 and each roller is driven in reverse. At this time, the leading end side of the card temporarily protrudes from the opening 96.

  Since the rear side of the card is guided by the restriction wall SW, the movement in the width direction is substantially restricted. Thereby, it is possible to effectively prevent the skew of the card even when the card is switched back. As described above, the scanner 8 according to the present embodiment has at least the discharge port 92 side and the opposite side (opening portion) of the conveyance / reading section 93 in the card conveyance path as the restriction wall portion for preventing the skew of the card. Each wall portion (conveying guide for the medium M) is provided in a portion corresponding to the (96 side). As a result, the scanner 8 of the present embodiment enables conveyance of the sheet medium S shown in FIG. 8 (first conveyance method described later), but also serves as a partial conveyance path for the sheet medium M (card). While realizing switchback conveyance (second conveyance method), skew of the sheet medium M can be effectively prevented, and the quality of image reading can be improved.

  The scanner 8 described in FIG. 8 and subsequent figures is a very compact image reading apparatus, and it is advantageous from the viewpoint of portability if power can be supplied by USB bus power. Therefore, if the power feeding method described with reference to FIGS. 1 to 7 is employed, usability can be further increased.

Claims (11)

A USB interface unit that can be connected to a host device compatible with the USB 3.0 standard using either a USB cable compliant with the USB 3.0 standard or a USB cable compliant with the USB 2.0 standard;
An energization condition changing unit that changes the current condition based on a voltage level of a connection terminal that is not used for data communication or current supply in the USB 2.0 standard among the connection terminals of the USB interface unit; peripheral and wherein the that. The connection terminal that is not used for data communication or current supply according to the USB 2.0 standard is a connection terminal that is connected to the 6th or 7th pin of the host device that supports the USB 3.0 standard by the USB cable. The peripheral device according to claim 1 , wherein: The power supply unit further includes a power supply unit that receives supply of current from the host device via the USB interface unit in accordance with an energization condition with the host device that matches a terminal connection state between the USB interface unit and the USB cable. the peripheral device according to claim 1 or 2, characterized in that also serves as a power unit for driving the main body of the peripheral device. A peripheral device with a load,
A USB interface unit that is connected to a host device via a single USB cable, transmits and receives data using the USB cable, and receives a current supplied by the host device;
A voltage detection unit that detects a voltage of a terminal that is not used for data transmission and reception among a plurality of terminals included in the USB interface unit and is not used for receiving the current;
If the voltage detected by the voltage detector is the first level, the upper limit value of the current supplied to the load is set to the first value, and if the voltage detected by the voltage detector is the second level, An upper limit setting unit that sets the upper limit of the current supplied to the load to the second value;
A current detector for detecting a current supplied to the load;
If the current detected by the current detection unit does not exceed the upper limit value set by the setting unit, the current supply to the load is continued, and the current detected by the current detection unit is set by the setting unit. If the upper limit is not exceeded, a current control unit that reduces the current supplied to the load;
A peripheral device comprising: An external power supply connection for receiving a current supplied from an external power supply different from the host device;
An external power source detection unit for detecting whether or not the external power source is connected to the external power source connection unit;
When the external power source detection unit detects that the external power source is connected to the external power source connection unit, the current supplied from the external power source is supplied to the first load among the loads, and the host When the current supply system is switched to supply the current supplied from the apparatus to the second load among the loads, and the external power source detection unit detects that the external power source is not connected to the external power source connection unit, The peripheral device according to claim 4 , further comprising: a switching unit that switches the current supply system so as to supply the current supplied from the host device to the first load and the second load. The first load is a load whose load fluctuation is small compared to the second load,
The peripheral device according to claim 5, wherein the second load is a load having a large load fluctuation as compared with the first load. Of the connectors at both ends of the USB cable, the first connector connected to the host device is a connector corresponding to the USB 3.0 standard, and the second connector connected to the peripheral device is a mini type of the USB 2.0 standard. Connector or micro B type connector,
The terminal that the voltage detection unit detects the voltage is the 4th pin of the second connector, and the 4th pin is any one of the 5th to 9th pins of the first connector by the USB cable. 4 claims, characterized in that it is connected to one to the peripheral device according to any one of 6. The 4th pin of the second connector is connected to the 7th pin of the first connector,
The voltage detector is
A pull-up resistor connected between the fourth pin and a reference voltage source;
The upper limit setting unit
When the potential at the connection point between the 4th pin and the pull-up resistor becomes low level, the upper limit value is set to 900 mA, and when the potential at the connection point between the 4th pin and the pull-up resistor becomes high level, The peripheral device according to claim 7 , wherein the upper limit value is set to 500 mA. Wherein the current detection unit, a peripheral device according to claim 7 or 8, characterized in that it comprises an inserted current-voltage conversion resistance between the pin 1 and the load in the USB2.0 standard. A control method for controlling a current supplied to the load in a peripheral device including the load,
Data among a plurality of terminals that are connected to a host device via a single USB cable, transmit and receive data using the USB cable, and have a USB interface unit that receives a current supplied by the host device. A voltage detection step of detecting a voltage of a terminal that is not used for transmission and reception of the current and that is not used for receiving the current;
If the voltage detected in the voltage detection step is the first level, the upper limit value of the current supplied to the load is set to the first value, and the voltage detected in the voltage detection step is the second level. An upper limit setting step for setting the upper limit value of the current supplied to the load to a second value;
A current detection step of detecting a current supplied to the load;
If the current detected in the current detection step does not exceed the upper limit value set in the setting step, the supply of current to the load is continued, and the current detected in the current detection step is determined in the setting step. And a current control step of reducing a current supplied to the load if the set upper limit value is not exceeded. A USB cable for connecting a host device and a peripheral device,
Of the connectors at both ends of the USB cable, the first connector connected to the host device is a connector compatible with the USB 3.0 standard, and the second connector connected to the peripheral device is the USB 3.0 standard or USB2. 0 standard connector,
Of the pins included in the second connector, a pin that is not used for communication or current reception is connected to any one of the fifth to ninth pins of the first connector. USB cable.

Images