NL1010000C2 - Integrated circuit for communication control. - Google Patents

Description

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Title: Integrated circuit for communication control.

Background of the Invention 1. Field of the Invention

The invention relates to an integrated communication control circuit, and in particular to an integrated communication control circuit for performing communication control of a next generation USB (Universal Serial Bus) network, which connects a personal computer to peripheral devices such as a keyboard, printer, and a display device.

2. Description of the prior art

A personal computer is connected to a number of peripheral devices such as a mouse, a keyboard, a computer. printer, a modem, a speaker and a display device. Interfaces between these peripheral devices and a personal computer are determined separately. In contrast, a USB is intended to make interfaces of such peripheral devices common. The USB is considered a network of the next generation. 20 The industry group "USB Implementers Forum" continues with standardization, dissemination promotion and interconnection test and the like. The communication specification of the USB is issued by the forum as "Universal Serial Bus Specification Revision 1.0" and the specification 25 can be downloaded from the web site http://www.usb.org/does.htm.

FIG. 9 is a diagram showing the concept of the USB. In this example, use is made of a personal computer 101 and a keyboard 111, a printer 112, a display device 113 and a scanner 114 are connected to the personal computer as peripheral devices thereof. A host function unit 121 is mounted on the personal computer 101. One host function unit 121 is arranged for one system and the host function unit 121 controls and controls the data transfer on a USB. The device functioning units 131 to 134 are mounted on the keyboard 111, the printer 112, the display device 113, and the scanner 114, connected to the personal computer 101, respectively. These device functioning units 131 to 134 transfer the data to 10 and receive it from the host function unit 121 via the USB.

The USB can have a tree structure. A core function unit 141 is required as a branch between the host function unit 121 and the device function units 132 to 134. The core function unit 141 has the function of a repeater, which transmits data from the guest. "downstream" to the device side (downstream), and performs data transfer in reverse ".

The respective peripheral devices can be attached to and even detached during the period when the USB system is operating. This is referred to as connecting and playing and is one of the characteristics of the USB. In a conventional interface, when a peripheral device is connected to the personal computer 101, the peripheral device can only be used after the power of the personal computer has been switched on again. In the case of the USB, when a peripheral device is connected, the host function unit 121 automatically recognizes the connection and integrates the peripheral device into the USB system so that data transfer is possible. Therefore, when a peripheral device is connected, the condition under which the peripheral device can be used is immediately established.

1010000 3

The core function unit 141 is used in the form of a single product, but in some cases can be built into a peripheral device. In the case where the core function unit is built into a peripheral device, the core function unit is combined with a device function unit of the peripheral device into which the core function unit is built. This combination is called a composite device. An example in which a composite device is built into a display device will be described below.

FIG. 10 is a diagram showing an example of a composite device for a display device. In this figure, a composite device 151, which is built into a display device 150, consists of a core function unit 152 and a device function unit 153 for the display device. The device function unit 153 for the display device comprises an I2C (Inter-Integrated Circuit) unit 154 and part of the functions of a microcontroller 155. The device function unit is connected to one of the downstream ports 156 to 160 of the core function unit 152 or, in this example, with the downstream port 160. The downstream ports 156 to 159 are for external peripheral devices, and the user can always attach or detach a USB device to the ports. The downstream port 160 is always physically connected to the device operation unit 153 for the display device. The composite device 151 is integrated into one chip and is provided by a semiconductor manufacturer as an integrated circuit for a communication control. In the microcontroller 155, the function of the microcontroller for controlling the display device is separated from the function of the 1010000 microcontroller that is determined as a composite device, and is formed by another chip.

A USB cable 162 connected to an upstream port 161 of the core function unit 152 consists of four lines, i.e. a pair of data lines D + and D-, and a pair of power supply lines V + and V-. The USB cable can carry out the transfer of serial data and the power supply in the downstream direction. The power supply system via the USB cable 162 is usually called a bus power supply.

The composite device 151 receives the power supply from the personal computer via the power supply lines of the USB cable 162. In contrast, the microcontroller 155 and the other electronic components of the display device 150 receive the power supply from a power supply circuit other than the bus power supply such as an AC / DC converter 163 on the display 150. This power supply system is used because the "maximum value of a current that can flow through one USB cable is limited to 500 mA and this value is not sufficient for the power supply to all electronic components on the display device 150. The AC / DC converter 163 in this example is called a local power supply.

The core function unit 152 plays a role in supplying power to the peripheral devices connected on the downstream side. As for the power supply, there are two methods, that is to say one method in which a current received from the upstream side is provided on the downstream side and another method in which the power is supplied from a power source built into the device itself . The first method is called a bus power method and the last method a self-power method. In the example of Fig. 10, the self-power method is used in which the power supply lines of the USB cable connected to the downstream ports 156 to 159 receive the power supply from the AC / DC converter 163. In other words the downstream peripheral devices collect the power supply from the AC / DC converter 163.

A conventional composite device, i.e. a conventional integrated communication control circuit, uses a power source that is separate from a micro-controller power source of a peripheral device on which the composite device is mounted. Therefore, in the case where one of the power sources fails, a chip that captures the power supply from the power source may not work or, after the power supply returns, one of the chips is sometimes reset to the initial state. For example, if the local power source providing the power to the microcontroller fails and the microcontroller cannot continue to operate, the integrated communication control circuit will continue to operate because the circuit has no function to sense the incorrect function. Only after the host function unit of the personal computer gives instructions to the microcontroller and a response from the microcontroller is not received, does the host function unit recognize that the peripheral device is in an abnormal condition. On the other hand, if the core power supply that supplies power to the integrated communication control circuit fails or after the core power supply returns, the microcontroller cannot sense that the integrated communication control circuit cannot work or that the circuit has been initialized by the return of the power supply. In an integrated communication control circuit consisting of a core function unit and a device function unit, a condition occurs in which a power supply abnormality of one of the units is not

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6 can be recognized by the other unit because it assumes that the internal connection between the core function unit and the device function unit is always ensured.

In this way, an integrated communication control circuit according to the state of the art has a problem in that a normal operating sequence cannot be ensured for various rising and falling sequences of power supply and a power supply abnormality.

Summary of the invention

The invention now provides a solution to the above problems. It is an object of the invention to provide an integrated circuit for communication control which has a core function unit and a device function and in which a wrong function will not occur even in the event that abnormal conditions occur in a power source for the integrated circuit for communication control or in a power supply for a peripheral device on which the integrated communication control circuit is mounted.

To solve the problem, the invention provides an integrated circuit for communication control, comprising: core function members for data transfer; device function means for performing data transfer from and to an external microcontroller; and enable sensing means for resetting the core function means and the device function means in response to a power supply from an upstream port of the core function means, the integrated communication control circuit further comprising connection information memory means arranged in the device function means for storing connection information indicating a connection 1010000 7 to the external microcontroller receiving power from a power source different from the power source of the core function members and the device function members, the connection information being reset when the beginning of a power supply from the upstream port is scanned by the switch-on scanners or when the external microcontroller is initialized, and the connection information that has been reset is set by the external microcontroller.

According to the integrated communication control circuit, when the connection is made with the host, the enable sensor senses the start of the power supply and resets the connection information from the connection information memory means. In response, the external microcontroller sets the connection information of the connection information memory means so that the integrated communication control circuit recognizes the connection to the external microcontroller. On the other hand, when an abnormality occurs in the power supply for the external microcontroller, the connection information of the connection information memory device is reset. Therefore, the integrated communication control circuit recognizes the disconnection of the external microcontroller. When the power supply of the external microcontroller returns to normal, the external microcontroller is reset. At this time, connection information from the connection information memory device is also reset. Therefore, the external microcontroller performs the initialization process and sets connection information from the connection information memory device. Therefore, the integrated communication control circuit recognizes the connection to the external microcontroller. As a result, the integrated circuit for communication 1010000 8 and the external microcontroller can mutually recognize the power supply abnormality of the other side. The host can not only recognize the connection condition with the integrated communication control circuit, but also the connection condition between the integrated communication control circuit and the external microcontroller.

Brief description of the drawings

FIG. 1 is a diagram illustrating the operating principle of the integrated communication control circuit according to the invention;

FIG. 2 is a diagram showing by way of example a configuration of a display device on which a USB composite device is mounted; FIG. 3 is a block diagram showing the internal configuration of the USB composite device;

FIG. 4 is a view showing commands and registers of the USB composite devices used to control a microcontroller; FIG. 5 is a block diagram showing the internal configuration of a function interface;

FIG. 6 is a flow chart (No. 1) that depicts an initial reset operation of the USB composite device; Fig. 7 is a flow chart (No. 2) showing the initial reset operation of the USB composite device;

FIG. 8 is a flow chart showing an operation when an abnormal condition from a local power source returns to a normal condition;

FIG. 9 is a diagram showing the concept of a USB; and

FIG. 10 is a diagram showing an example of a composite device for a display.

1010000 9

Detailed description of the preferred embodiments

Hereinafter, an embodiment of the invention will be described with reference to the drawings.

FIG. 1 is a diagram illustrating the operating principle of the integrated communication control circuit according to the invention. The integrated communication control circuit 1 comprises: core function members 2, which are connected to external host function members and a plurality of device function members, for performing retransmission of the data transfer; device function members 3, which are connected to the core function members 2 for performing data transfer from and to an external microcontroller 6; and switch-on sensing means 4 connected to power supply lines providing power from the host function means to the core function means 2 for detecting an onset of power supply. In the integrated communication control circuit 1 according to the invention, the device function means 3 comprises connection information memory means 5. The external microcontroller 6 receives a power supply from power supply means 7 and is designed such that it is reset in the event of a power supply abnormality and means 8 for sensing a normal return sensing an abnormal drop or a normal return of an output voltage from the power supply means 7.

The connection information memory device 5 of the device function device 3 is reset when the connection to the host function device is made and the switch-on sensor device 4 senses the start of the power supply from the host function device. Subsequently, an interrupt occurs to the microcontroller 6, and the microcontroller 6 sets the connection information indicating the 1010000 connection from the device function means 3 to the microcontroller 6 to the connection information memory means 5. Therefore, the integrated circuit 1 can communication controller recognize the connection with the external 5 microcontroller 6.

The connection information memory device 5 of the device function unit 3 is also reset when the device 8 for sensing the power supply abnormality and the normal return senses an abnormal drop 10 of a source voltage supplied to the microcontroller 6 and the microcontroller 6 reset. Therefore, the integrated communication control circuit 1 can recognize the disconnection of the external microcontroller 6.

Moreover, the connection information memory device 5 of the device function device 3 is also reset when the device 8 for sensing the power supply abnormality and the normal return senses a normal return of the source voltage supplied to the microcontroller 6 and the microcontroller 6. reset. Then an interrupt occurs to the microcontroller 6, and the microcontroller 6 sets the connection information indicating the connection from the device function member 3 to the microcontroller 6 to the connection information memory member 5. Therefore, the integrated communication control circuit 1 can with the external microcontroller 6.

In this way, the integrated communication control circuit 1 and the microcontroller 6 can mutually recognize the power supply condition from the other side and both can perform proper communication without causing an operation abnormality to return from an abnormal power supply condition from the other side.

1010000 11

In the following, the integrated communication control circuit according to the invention will be described in detail by describing an example in which the device is applied to a USB composite device in which a USB core function is mounted on a display device and communication with a microcontroller for the display device is performed via an I2C unit.

FIG. 2 is a diagram showing a configuration of a display device on which a USB composite device is mounted by way of example. An upstream USB cable 11 is connected to an upstream port of the USB compound device 10. Downstream USB cables 12, 13, 14 and 15 are connected to downstream ports of the USB compound device 10. The upstream USB cable 11 is connected to a host function unit mounted on a personal computer. The downstream USB cables 12, 13, 14 and 15 are connected to peripheral devices such as a keyboard, a mouse, a printer and a scanner on which a USB device function is mounted. Each USB cable is formed by four lines, i.e. a pair of data lines D + and D- for transferring serial data and a pair of power supply lines V + and V- for supplying power downstream.

The display device comprises: an AC / DC converter 20 which serves as a power supply for the display device; a microcontroller 21 for controlling the display device; a read-only memory (ROM) 22 that stores 30 programs for controlling the display device; a memory (RAM) 23 for executing a program and for storing data; and an initialization circuit 24 which outputs a reset signal RST2 in an abnormal condition and on the normal return of the source voltage supplied from the AC / DC converter 20. The microcontroller 21 and the USB assembled device 10 are with interconnected by the I2C bus 25 and an interrupt line (INT) 26. An output of the initialization circuit 24 is connected to the microcontroller 21 and the USB composite device 10.

The USB composite device 10 performs a data transfer from and to the microcontroller 21 via the I2C bus 25. The USB composite device 10 indicates to the microcontroller 21 a change of an internal condition and a request for data transfer through to use the interrupt line 26.

The USB composite device 10 is directly connected to the power supply lines V + and V- of the upstream USB cable 11 to receive the supply of a bus power supply from the host function unit. In contrast, the power supply lines V + and V- of the downstream USB cables 12, 13, 14 and 15 are designed to receive a power supply from the power source for the display device, i.e. from the AC / DC converter 20 which serves as local 20 power source. Overcurrent detection units 31, 32, 33 and 34 and switches 35, 36, 37 and 38 are inserted between the AC / DC converter 20 and the power supply lines V + and V- of the downstream USB cables 12, 13, 14 and 15 respectively . Overcurrent detection outputs of the overcurrent detection units 31, 32, 33 and 34 and switch control inputs of the switches 35, 36, 37 and 38 are connected to the USB composite device 10.

The overcurrent detection units 31, 32, 33 and 34 and the switches 35, 36, 37 and 38 form a protection circuit as a countermeasure against short-circuiting of a power supply line of the downstream USB cables 12, 13, 14 or 15 and a failure of a peripheral device. When an overcurrent is detected by overcurrent detection unit 31, 32, 33 or 34, a detection signal 35 is input to the USB composite device 10 and one of the switches 35, 36, 37 and 38 corresponding to 10 '! 0000 13 the signal is switched off. In addition, the USB composite device 10 reports the occurrence of the overflow to the host function unit of the personal computer. Typically, each overcurrent detection unit 31, 32, 33, and 34 converts a current flowing through a resistor into a voltage and compares the converted voltage to a threshold voltage by using a comparator to detect an overcurrent. A threshold value through which the overcurrent is determined is set at 600 to 1000 mA for one cable.

The overflow detection units 31, 32, 33 and 34 and the switches 35, 36, 37 and 38 are arranged outside the USB composite device 10. Preferably, the integrated communication control circuit can be designed to include these components.

Pig. 3 is a block diagram showing the internal configuration of the USB composite device.

The USB composite device 10 comprises a core function unit 40, and an I2C unit 41 that performs communication 20 with the microcontroller 21 for the display device. The core function unit 40 is formed by a core repeater 42, a serial interface machine 43, and a core controller 44. The I2C unit 41 consists of a function interface 45. At a current up port of the core repeat device 42 of a core function unit 40, a transceiver 46 is provided for connection to the host function unit of the personal computer. At downstream ports, transceivers 47, 48, 49 and 50 are provided for the connections to peripheral devices. A power enable reset circuit 51 is connected to power supply lines of the upstream USB cable. The power switch-on resetting circuit 51 senses the start of the voltage supply of the core power supply and outputs an reset signal RST1. An output of the power enable reset circuit 51 is connected 14 to reset inputs of the core repeater 42, the serial interface machine 43, and the core controller 44. A logic OR circuit 52 is provided. The logic OR circuit 52 receives as input 5 the reset signal RST1, which is the output of the power switch-on reset circuit 51 and the reset signal RST2 for resetting the microcontroller 21 for the display device. An output of the logic OR circuit 52 is connected to the function interface 45 of the I2C unit 41.

The core repeater 42 transfers data from the host side (upstream) to the device side (downstream) and performs data transfer in the reverse direction. The serial interface machine 43 performs the coding and decoding of data prescribed by USB protocols and the extraction of bit clocks from the received data, to perform a conversion between the transmitted data and a signal which occurs at that time on the bus. The core controller 44 is provided for a control instruction and a control instruction of the internal condition from the host. In the core controller 44, a block exists that is called a descriptor and in which information related to the core configuration is described. In accordance with a request from the host function unit, required data is read from the block. The function interface 45 has the function to cause the microcontroller for the display device to perform data transfer via the IaC unit 41.

The transceivers 46 to 50 at the respective ports of the core repeater 42 represent the conversion between a digital signal and a differential analog signal (D + and D-) on the bus. By using the potentials of the data lines D + and D- it is possible to control not only the data transfer but also the device connection condition. Therefore, the host 1010000 and the core can recognize the hooking and loosening of a device at their downstream ports.

The I2C unit 41 functions as one of the device functions that is connected to the host in the same way as the device function that is connected to the transceivers 47 to 50 on the downstream side. The I2C unit 41 is always in physically connected condition.

FIG. 4 is a view showing commands and registers 10 of the USB composite device used to control the microcontroller. The commands and registers shown are used by the microcontroller 21 for performing data transfer via the I2C unit and for controlling the internal condition of the USB composite device 10. As registers are a device address register, control and control registers for two end points, buffers for two end points, and a function status register. The function status register is at least performed by an RST bit, an ENB bit, a SUSP bit and a CONN bit.

The RST bit indicates that the core is in the condition that it receives a reset command from the host function unit. The SUSP bit indicates that the core is in a floating condition because there is no data transfer for a predetermined or longer period of time. The ENB bit usually indicates a condition where the core is recognized by the host function unit. In the invention, the ENB bit indicates a condition where the host function unit recognizes that the device is connected to a port to which the I2C unit 41 is connected. When the ENB bit is set or reset, the interrupt line (INT) 26 is active. The CONN bit is a bit used new in the invention.

The CONN bit is set by the microcontroller 21 and 35 indicates that the core function unit and the device function unit are logically connected. The CONN bit 1010000 16 is reset by the reset signal RST1 by the power enable reset circuit 51 and the reset signal RST2 for the microcontroller 21 thereby making the interrupt line (INT) 26 active.

These registers and buffers are arranged in the function interface 45 of the I2C unit 41. Next, the internal configuration of the function interface 45 of the I2C unit 41 will be described.

FIG. 5 is a block diagram showing the internal configuration of the function interface. The function interface 45 consists of a device address register 61, an end point 62 called "ENDPointO", an end point 63 called "IN ENDPoint" and a function status register 64. The end point 62 consists of a control 15 and control register 65 and a buffer 66. The end point 63 consists of a control and control register 67 and a buffer 68. The buffers 66 and 68 of the end points 62 and 63 are data buffers of FIFO (First In First Out) or the like.

The device address register 61 stores an address of the device function unit on the USB. The core function unit 40 receives the address issued by the host function unit and the microcontroller 21 reads the received address and writes it to the device address register 61 to determine the address of the device function unit on the USB. The end point 62 is used when the control and control are performed between the personal computer and the display device. The control and control register 65 is used for writing and reading a command and the data is transferred via the buffer 66. The end point 63 is used in the case where the microcontroller 21 has a request to the host function unit. The end point 63 writes a command to the control and control register 67 and reads the condition. The data transfer to the host function unit becomes 10; oo o o 17 performed via the buffer 68. The function status register 64 is used for the microcontroller to know the status in the core function unit, and holds the bit information shown in Fig. 4.

In the following, an initial setup operation is described in which a USB composite device 10 is actually energized when a display device is connected to a personal computer by a USB cable.

FIG. 6 and 7 are flow charts illustrating the initial setup operation of the USB composite device.

First, the USB composite device 10 is connected to the USB cable 11 of the personal computer. The host function unit mounted on the personal computer scans the connection and generates a reset to the USB composite device 10. When the core function unit 40 responds to this, the host function unit examines the core function unit 40 for the condition of the core and the conditions of the ports. Specifically, the host function unit reads the core descriptor located in the descriptor of the core controller 44 of the core function unit 40. At this time, the core descriptor indicates that the core is a composite device, but does not indicate a built-in device device for a composite device is connected. From these indications, the host function unit recognizes that a device is not connected to the ports of the core. Next, the host function unit outputs the core address setting to the core function unit 40. The core function unit 40 receives this, determines the address of the core and gives the response to the host function unit. The host function unit then instructs the configuration of the configuration to the core function unit 40. When the configuration is complete, the core function unit 40 responds to the host function unit.

1070000 18

In contrast, in the core function unit 40 of the USB composite device 10, the power enable reset circuit 51 outputs the reset signal RST1 in response to the supply of the core power supply 5, so that the core function unit 40 itself and the function status register 64 of the I2C unit 41 is initialized. In the initial condition of the USB compound device 10, the CONN bit is reset to 0 and then an interrupt to the microcontroller 10 21 occurs. For the microcontroller 21 to know the reason for the interrupt, the microcontroller 21 refers to the function status register 64 and recognizes that the CONN bit is 0. The CONN bit is then set as 1. By this setting, the core function unit 40 recognizes that a device is connected to a port and announces the change of the port status to the host function unit. In response, the host function unit issues a port reset and assigns a port effectiveness to the corresponding port. At this time, the ENB bit and the RST bit of the function status register 64 are set as 1. In response to the interruption that occurs when the ENB bit is set, the microcontroller 21 refers to the function status register 64 and knows that the ENB bit is set, and recognizes that the USB composite device 10 is connected to the personal computer.

The host function unit then outputs a request from the device descriptor, and the I2C unit 41 then outputs a data processing request to the microcontroller 21 to require data related to the device. By means of an interrupt process, the microcontroller 21 first reads the command of the received request, prepares the data related to the display device and transmits the data. The IaC unit 41 receives the data and sends the data to the host function unit. Subsequently, 1010000 19, the host function unit interprets the contents of the device descriptor and outputs an address setting of the device to assign an address to the device. The I2C unit 41 allows the microcontroller 21 to perform the data processing for the address setting of the device. In the interrupt process, the microcontroller 21 reads the command of the received request and writes the address of the device to the device address register 61 of the I2C unit 41 to determine the address of the device. Then, when the host function unit executes a command for the configuration device, the I2C unit 41 causes the microcontroller 21 to perform data processing for the configuration. By means of an interrupt process, the microcontroller 21 reads the command of the request received and sets the configuration of the device. When the configuration setting is complete, the microcontroller 21 outputs an answer to the host function unit. In this way the initial setting of the USB composite device is completed. Since the connection is recognized, data transfer between the host function unit and the microcontroller 21 is then started.

Since the microcontroller 21 for the display device and the USB composite device 10 use different power sources, in this embodiment the case may occur in which the power source is disconnected in one of the two directions and the connected chip cannot work. In the invention, therefore, different reset signals are applied to the core function unit 40 and the I2C unit 41. The reset signal RST1 in FIG. 3 is a power enable reset signal that utilizes the core power source as the power source of the integrated circuit and is 35 is produced by the power on / reset circuit 51. The reset signal RST1 becomes 1010000.

20 is brought to each power input of the USB composite device 10 and is applied to the entire integrated circuit whereby the initialization is performed. The reset signal RST2 is also used for the I2C unit 41. However, the reset signal RST2 becomes active when a voltage drops or returns to a normal voltage from the local power source that supplies a power to the microcontroller. The reset signal RST2 is also applied to the microcontroller 21 as a reset signal.

First, a case will be described in which the local power source providing power to the microcontroller 21 fails.

FIG. 8 is a flow chart showing the operation on a normal return from an abnormality of the local power source. When the voltage of the AC / DC. converter 20 is normal, the CONN bit and ENB bit of the function status register in the I2C unit 41 are set as 1. In the case where the microcontroller 21 is reset by a reason such as a voltage drop from the local power source or is in a condition where the microcontroller 21 cannot function, the I2C unit 41 is also reset. At this time, the CONN bit and the ENB bit of the function status register in the function interface 45 are also reset. The core function unit 40 scans the reset and announces the change of the port status to the host function unit on the personal computer. Therefore, the host function unit notices that the connection to the microcontroller 21 has been eliminated and recognizes that the device function has been broken from the corresponding port.

Then, when the local power source returns and the microcontroller 21 begins to operate normally, the microcontroller 21 and CONN bit are reset. Since the CONN bit of the I2C unit 41 is 0, an interrupt for the microcontroller 21 occurs at this time.

101000Q

21

From the reset condition of the CONN bit, the microcontroller 21 knows that the self-USB device function has been broken from the core and sets the CONN bit to 1. The core function unit 40 scans this setting and informs the host function unit of the change of the port status. Therefore, the host function unit scans the connection, outputs the port reset to the core function unit 40 and assigns a port effectiveness to the corresponding port. At this time, the ENB bit and the RST bit of the I2C unit 41 are set as 1. Due to the interruption that occurs when the ENB bit is set, the microcontroller 21 refers to the function status register 64 and knows that the ENB bit is set. In this way, the microcontroller 21 recognizes that the USB composite device is connected to the personal computer. Thereafter, an operation that is the same as the connection operation at the initial setting shown in FIG. 7 is repeated. When the address setting of the device and the configuration of the device are complete, the connection operation is completed after the return of the local power source.

Next, a case will be described where the bus power source fails and the USB composite device 10 is reset. First, when there is no supply from the bus power source, a non-response condition occurs with respect to a call from the microcontroller 21. Therefore, the microcontroller 21 can determine that an abnormality occurs in the bus power source.

When the bus power supply returns, the USB composite device 10 is reset by the reset signal RST1 which is output from the power enable reset circuit 51. After the return of the bus power supply, therefore, an operation identical to the initial setting operation is shown in FIG.

6 and 7.

1010000.

22

As described above, according to the invention, an integrated circuit for communication control means comprises for storing connection information indicating a connection of core function means to device function means. The connection information memory means are reset by the integrated communication control circuit itself and an external microcontroller, and are set by the microcontroller. Therefore, the microcontroller 10 may know whether the core has been reset by a reason such as stopping the power supply from a core power source or not. Furthermore, the host can recognize whether the microcontroller has been disconnected from the port due to a power supply stop from a local power source or not. It is therefore possible to realize gradual communication with high reliability.

1010000

Claims (6)

1- Integrated circuit for communication control, comprising: core function members for data transfer; device function means for performing data transfer from and to an external microcontroller; and power enable sensing means for resetting the core function means and the device function means in response to a power supply from an upstream port of the core function members; wherein the integrated communication control circuit further comprises connection information memory means arranged in the device function means for storing connection information 15 indicating a connection to the external microcontroller receiving power from a power source different from the power source of the core function means and device function means, wherein the connection information is reset when a start of a power supply is scanned from the upstream port by the power enable sensor or when the external microcontroller is initialized, and connection information that is reset is set by the external micro-25 controller. 2. Integrated circuit for communication control according to claim 1, characterized in that the connection information memory means consist of a register in which a bit value when the connection information is set differs from a bit value when the connection information is reset. An integrated communication control circuit according to claim 1, characterized in that by reference 1010000 to the connection information upon resetting in the connection information memory means both the core function means and the external microcontroller recognize that the connection of the core function means and the external 5 microcontroller has been broken. 4. Integrated circuit for communication control according to claim 1, characterized in that when connection information is reset in the connection information memory means, the device function means causes a state of an interrupt connection provided for the external microcontroller to be active. 5. Integrated circuit for communication control as claimed in claim 1, characterized in that furthermore are present: overcurrent detection means arranged on a power supply line of a cable connected to each downstream port of the core function members for detecting that a current having a value equal to or greater than a predetermined value flows through the power supply line; and switching means which, when an overflow is detected by the overflow detection means, interrupts the power supply line. 6. A communication control system, which is arranged in one device and performs a data transfer between a host, the device and a device of another system, the communication control system comprising: an integrated circuit for communication control, comprising: core function members for executing of data transfer between a host and a number of devices; device function means connected to the core function means as one of a plurality of devices, and comprising connection information memory means for storing connection information indicating connection of the core function means to the device; and power enable sensing means for resetting the connection information memory means when 1010000 4 power is provided from the host; a local power source, which provides a source voltage for the device of a system independent of a power source of the host; a device control microcontroller that is arranged to control the device of a system and which sets the connection information memory means upon initialization; and power supply abnormality and normal return sensing means for resetting a microcontroller and the connection information memory means in an abnormal condition and with a normal return of the local power source. iOiOOOO