JP2004180040A - Portable terminal device and signal control circuit - Google Patents

Abstract

When two CPUs are connected by one data bus, when a master CPU of the data bus performs a memory access, a change in a signal line such as a data bus changes on a CPU side connected to the data bus as a slave. The input buffer, the internal circuit, and the like are operated unnecessarily, and an unnecessary current flows, so that a standby time and a talk time are shortened.
A first control means opens a gate means when performing display, sends display data to a second control part to perform display, and closes the gate means when performing memory access. The connection between the control means and the inside of the second control means is disconnected.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a portable terminal device that performs voice / data communication using a wireless line, and relates to a portable terminal device having two CPUs.
[0002]
[Prior art]
As a conventional two-CPU mobile phone, a mobile phone is provided with two CPUs, a communication CPU and a mobile game CPU, and displays on the same liquid crystal using different signal lines from both CPUs. (For example, see Patent Document 1).
[0003]
[Patent Document 1]
JP 2001-136250 A (Page 4, FIG. 6)
[0004]
[Problems to be solved by the invention]
However, in a configuration in which two CPUs perform display on the same liquid crystal from different signal lines as in Patent Document 1, when each CPU outputs display data at its own timing, the transfer timing of the display data overlaps. If this happens, it is expected that display data will be corrupted and display errors will occur.
[0005]
When two CPUs are connected using one of the data buses, the data transmission / reception operations of the two CPUs include not only the data transmission / reception between the two CPUs but also, for example, the case where each CPU performs memory access. In this case, a change in a signal line such as a data bus operated for memory access by a master CPU of the data bus causes unnecessary operation of an input buffer and an internal circuit of the CPU connected to the data bus as a slave. This causes unnecessary current to flow. In this case, the power consumption of the entire mobile phone increases, and the standby time and the talk time are shortened.
[0006]
[Means for Solving the Problems]
In order to solve the above problems, a portable terminal device of the present invention has first control means, second control means, and display means for displaying an image, and the second control means displays image information. An arithmetic means for processing, a gate means for selecting whether or not to transmit an input signal from the first control means to the inside by a control signal transmitted from the first control means; And display data selection means for selecting the display data processed and output by the arithmetic means. The display means displays an image based on the display data selected by the display data selection means.
[0007]
With this configuration, the display processing by the two control means can be smoothly performed, and the second control section may cause a case where the first control section does not transmit / receive data to / from the second control section. It is possible to prevent unnecessary activation of the internal circuit due to a change in the data bus of the first control unit, and it is possible to reduce unnecessary current consumption.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described with reference to the drawings. In the present embodiment, the present invention is applied to a mobile phone as a mobile terminal device.
[0009]
FIG. 1 is a block diagram showing the internal circuit configuration of the first embodiment of the present invention, wherein 1 is an antenna, 2 is a wireless communication unit, 3 is a code compound processing unit, 4 is a microphone, 5 is a receiver, and 6 is A display unit, 7 is an input unit such as a key, 81 is a memory A for the first control unit 9, 82 is a memory B for the second control unit 10, and 9 is a first for mainly performing a wireless communication protocol process. The control unit 10 is a second control unit that mainly performs protocol processing of multimedia data.
[0010]
Further, in the second control unit, 101 is a CPU unit for performing arithmetic processing, 102 is an internal circuit formed by peripheral modules other than the CPU unit 101, and 103 is a first circuit under the control of the first control unit. A gate unit 104 for preventing data output from the control unit from being transmitted to the second control unit 104 selects the display data output from the CPU unit 101 and the display data output from the first control unit 9. A data selection unit 105 for outputting to the display unit 6 is a connection terminal for connecting to a data bus-related signal line of the first control unit and transmitting and receiving various data.
[0011]
Reference numeral 121 denotes a data bus related signal of the first control unit, 122 denotes a data bus related signal of the second control unit, and 123 controls the gate unit 103 to determine whether the data input from the connection terminal 105 is taken in. A data take-in chip select signal (hereinafter referred to as a CS1 signal) to be determined, a data output signal A connecting the CPU 101 of the second control unit 10 and the data selection unit 104, and a gate output unit 125 via the gate unit 103 The data output signal B connects the connection terminal 105 to the internal circuit 102 and the data selection unit 104.
[0012]
Hereinafter, the operation of each unit will be described. The antenna 1 receives a radio wave transmitted in the air, converts the radio wave into a high-frequency electric signal, and inputs the high-frequency electric signal to the wireless communication unit 2. Conversely, the high-frequency electric signal output from the wireless communication unit 2 is converted into a radio wave and emitted into the air. The radio communication unit 2 demodulates the high-frequency electric signal received by the antenna 1 based on an instruction from the first control unit 9 and inputs the demodulated high-frequency electric signal to the code decoding processing unit 3. Conversely, the output signal of the codec 3 is subjected to modulation processing, converted into a high-frequency electric signal, and output to the antenna 1. After performing a decoding process on the output signal of the wireless communication unit 2, the code decoding processing unit 3 outputs the audio data to the receiver 5, and outputs the character data and the image data to the first control unit 9. On the contrary, the output signal of the microphone 4 and the output signal of the first control unit 9 are subjected to encoding processing and output to the wireless communication unit 2. The microphone 4 converts the audio data into an electric signal, and outputs the electric signal to the code decoder 3. The receiver 5 converts the audio output signal output from the codec 3 into audio.
[0013]
The first control unit 9 is a unit for mainly performing processing related to a communication protocol, and performs communication processing as a mobile phone by controlling the above-described units. However, the processing related to the communication-related application is also performed by the first control unit 9. The second control unit 10 is a unit for executing an application having a heavy processing load among various applications realized by the mobile phone, and mainly performs a compression / expansion process of still image data and moving image data. , And performs processing of applications related to multimedia, such as music reproduction processing. The two control units require memories for storing various programs and data, and are connected to respective data buses, and frequently read / write data.
[0014]
The display unit 6 is connected to the data bus 122 of the second control unit 10. This is because the main processing contents of the two control units are compared, and it is considered that it is better to connect to the control unit side which seems to output a large amount of data to the display unit 6.
[0015]
In the case of this configuration, since the display unit 6 is connected to the data bus 122 of the second control unit 10, when the first control unit 9 wants to perform display, the display data is transferred to the first control unit 9. The data is sent from the data bus 121 to the second control unit 10, output to the display unit 6 via the data bus 122 of the second control unit 10 via the gate unit 103 and the display data selection unit 104, and displayed. Become.
[0016]
The data bus 121 of the first control unit 9 is connected to the second control unit 10 via the connection terminal 105, and data transmission and reception between the two control units is also used. The data capture chip select signal 123 is connected to the general-purpose port of the first control unit 9 and controls on / off of the gate unit 103 at an arbitrary timing.
[0017]
Hereinafter, the first embodiment of the present invention will be described with reference to the flowchart of FIG. When the power of the mobile phone is turned on, the first control unit 9 and the second control unit 10 start operating (S100). Normally, a standby screen is displayed on the mobile phone immediately after the power is turned on, so that the display data selection unit 104 selects display data output from the second control unit that performs image processing (S101). .
[0018]
In this state, if the first control unit 9 does not transfer data to the second control unit 10 (No in S102), the first control unit 9 sets the data capture chip select signal 123 to disable. By doing so (S103), the gate unit 103 in the second control unit 10 is turned off so that data output from the data bus 121 of the first control unit 9 is not transmitted to the second control unit 10. (S104). Accordingly, for example, even when the first control unit transmits and receives data to and from the memory A81 connected to the data bus 121 of the first control unit 9 (S105), the High / Low change of the data bus 121 is not changed. The internal circuit 102, the input buffer, and the like in the second control unit 10 are operated extra, and it is possible to suppress unnecessary current.
[0019]
In this case, when the first control unit 9 transmits and receives data to and from the data bus 121 of the first control unit 9, for example, the memory A81, the second control unit 10 transitions to the standby state. Or an application or the like may be running. It suffices that data transmission and reception do not occur between the first control unit 9 and the second control unit 10 and the respective units operate independently.
[0020]
Next, when the first controller 9 transfers data to the second controller 10 (Yes in S102), the first controller 9 sets the data capture chip select signal 123 to enable. (S106), the gate circuit 103 in the second control unit 10 is turned on so that data output from the data bus 121 of the first control unit 9 is transmitted to the second control unit 10 (S107). ).
[0021]
In a state where the second control unit 10 is executing the multimedia-related application, the second control unit 10 cannot naturally transition to the standby state (No in S108). Therefore, data such as still images / moving images and text characters required for multimedia-related applications are generated by the CPU unit 101 of the second control unit 10 and displayed by the data output signal A124 output from the CPU unit 101. The data is output to the data selection unit 104. The display data selection unit 104 selects the display data output from the second control unit 10 because the second control unit 10 has not transitioned to the standby state, and sets the data bus 122 of the second control unit 10 to the standby state. The display data is output to the display unit 6 via the display unit (S109), and the data is displayed (S110). In this state, the first control unit 9 transmits and receives data to and from the internal circuit 102 of the second control unit 10 (S111).
[0022]
Further, when all the application processing in the second control unit 10 is completed and only the standby screen is displayed, the mobile phone generally uses the standby mode in the low power consumption mode in order to improve the battery life. Transition to the state (Yes in S108). When the second control unit 10 transitions to the standby state, the screen display by the second control unit 10 is not performed, and thus the output source of the display data to the display unit 6 is the first control unit 10 from the second control unit 10. It moves to the part 9. Therefore, in response to the transition of the operation mode of the second control unit 10 to the standby state, the setting of the display data selection unit 104 is changed so as to select the display data input from the first control unit. (S112). As a result, the display data output from the data bus 121 of the first control unit 9 is input to the second control unit 10 via the connection terminal 105 of the second control unit 10, and the previously set data The data is sent to the display data selection unit 104 via the gate unit 103 turned on by the enable setting of the capture chip select signal 123. The display data selection unit 104 selects the display data output from the first control unit 9 and outputs the display data to the display unit 6 via the data bus 122 of the second control unit 10 (S113). Is displayed (S110).
[0023]
If the second control unit 10 remains in the standby state (No in S114), no data is sent from the second control unit 10, so the process returns to S113 and the first control unit 9 The output display data is output to the display unit 6 to continue the display, and when the standby state is released (Yes in S114), the process returns to S101 and the display data of the display data selection unit 104 is temporarily controlled by the second control. Switching to the unit 10 side, and the same processing is performed thereafter.
[0024]
In the present embodiment, the data bus of the control unit, which is a parallel bus, has been described as an example, but the unit connecting the two control units is a digital bus synchronized with a horizontal / vertical synchronization signal such as a serial data bus or a video interface. Even a video signal does not depart from the present invention.
[0025]
A second embodiment of the present invention will be described. FIG. 3 is a block diagram showing a second embodiment of the present invention. The same functional portions as those in FIG. 1 are denoted by the same reference numerals, and description of the same functional portions is omitted.
[0026]
Reference numeral 126 denotes a peripheral device chip select signal (hereinafter, referred to as a CS2 signal) for transmitting and receiving data to and from a peripheral device connected to the data bus 121 of the first control unit 9.
[0027]
Usually, in the case of a data bus to which a plurality of devices are connected, a chip select signal is used to specify a data transmission / reception destination. One chip select signal is connected to each device connected to the data bus, and only when data transmission / reception occurs, the chip select signal of the corresponding device is enabled to transmit / receive data. No two chip select signals are enabled at the same time. Here, the chip select signal is described as a Low active signal.
[0028]
Hereinafter, a second embodiment of the present invention will be described with reference to the flowchart of FIG. 4 and the data transmission / reception timing chart of FIG. When the power of the mobile phone is turned on, the first control unit 9 and the second control unit 10 start operating (S100). At this time, all chip select signals for transmitting and receiving data to and from a plurality of devices connected to the data bus 121 of the first control unit 9 are disabled. Therefore, the gate unit 103 of the second control unit 10 is off (S200). Since the mobile phone displays a standby screen immediately after the power is turned on, the display data selection unit 104 selects display data output from the second control unit that performs image processing (S101). .
[0029]
In this state, when the first control unit 9 does not transfer data to the second control unit 10 (No in S102), the first control unit 9 transmits a chip select signal of a peripheral device to which data transmission / reception is desired. To the enable state to transmit and receive data. In FIG. 3, since the memory A81 is connected to the data bus 121 of the first control unit 9 in addition to the second control unit 10, the case of transmitting and receiving data to and from the memory A81 will be described. The first control unit controls the CS2 signal, controls the peripheral device chip select signal 126, and enables the device select signal of the memory A81. The first control unit 9 transmits and receives data while the memory A81 is enabled (S201). Since the CS2 signal is not a signal for turning on / off the gate unit 103, the gate unit 103 is always turned off during the CS1 signal disable period as shown in FIG. 5, and thus is output from the data bus 121 of the first control unit 9. The transmitted data is not transmitted to the second control unit 10. Therefore, a change in High / Low of the data bus 121 causes the internal circuit 102, the input buffer, and the like in the second control unit 10 to operate extra, and it is possible to suppress an unnecessary current.
[0030]
In this case, the second control unit 10 may transition to the standby state, or may be executing an application or the like. It suffices that data transmission / reception does not occur between the first control unit 9 and the second control unit 10 and the respective units operate independently.
Next, when the first controller 9 transfers data to the second controller 10 (Yes in S102), the operation differs depending on whether the second controller 10 is in the standby state.
[0031]
In a state where the second control unit 10 is executing the multimedia-related application, the second control unit 10 cannot naturally transition to the standby state (No in S108). Therefore, data such as still images / moving images and text characters required for multimedia-related applications are generated by the CPU unit 101 of the second control unit 10 and displayed by the data output signal A124 output from the CPU unit 101. The data is output to the data selection unit 104. The display data selection unit 104 selects the display data output from the second control unit 10 because the second control unit 10 has not transitioned to the standby state, and sets the data bus 122 of the second control unit 10 to the standby state. The display data is output to the display unit 6 via the display unit (S109), and the data is displayed (S110). The first control unit 9 enables the CS1 signal to transmit and receive data to and from the second control unit 10. During the period when the CS1 signal is enabled, the gate unit 103 is turned on by the data fetching chip select signal 123, and data can be transmitted and received between the first control unit 9 and the internal circuit 102 of the second control unit 10. It becomes possible (S202).
[0032]
Further, when all the application processing in the second control unit 10 is completed and only the standby screen is displayed, the mobile phone generally uses the standby mode in the low power consumption mode in order to improve the battery life. Transition to the state (Yes in S108). When the second control unit 10 transitions to the standby state, the screen display by the second control unit 10 is not performed, and thus the output source of the display data to the display unit 6 is the first control unit 10 from the second control unit 10. It moves to the part 9. Therefore, in response to the transition of the operation mode of the second control unit 10 to the standby state, the setting of the display data selection unit 104 is changed so as to select the display data input from the first control unit. (S112). The first control unit 9 enables the CS1 signal to output data to the second control unit 10. While the CS signal 1 is in the enable period, the gate unit 103 is turned on by the data fetching chip select signal 123 as shown in FIG. 5 so that the data output from the first control unit 9 can be output to the second control unit 10. (S203). Accordingly, the display data output from the data bus 121 of the first control unit 9 is input to the second control unit 10 via the connection terminal 105 of the second control unit 10 and passes through the gate unit 103. Then, it is sent to the display data selection unit 104. The display data selection unit 104 selects the display data output from the first control unit 9 and outputs the display data to the display unit 6 via the data bus 122 of the second control unit 10 (S113). Is displayed (S110).
[0033]
If the second control unit 10 remains in the standby state (No in S114), no data is sent from the second control unit 10, so the process returns to S113 and the first control unit 9 The output display data is output to the display unit 6 to continue the display, and when the standby state is released (Yes in S114), the process returns to S101 and the display data of the display data selection unit 104 is temporarily controlled by the second control. Switching to the unit 10 side, and the same processing is performed thereafter.
[0034]
In the present embodiment, the selection switching of the input data of the display data selection unit is automatically switched depending on whether the operation mode of the second control unit 10 has transitioned to the standby state. The second control unit 10 may manually switch the display data selection unit before the transition to, or switch the display data in another operation mode.
[0035]
A third embodiment of the present invention will be described. FIG. 6 is a block diagram showing a third embodiment of the present invention. The same functional portions as those in FIG. 1 are denoted by the same reference numerals, and description of the same functional portions is omitted.
[0036]
127 is a display data selection instruction signal of the display data selection unit 104, for example, a general-purpose port of the first control unit 9 is used. When the display data is transmitted from the first control unit 9, the display data selected by the display data selection unit 104 is converted to the display data output from the first control unit 9 by the display data selection instruction signal 127. Is selected, otherwise, control is performed to select display data output from the second control unit 10.
[0037]
Hereinafter, a third embodiment of the present invention will be described with reference to the flowchart of FIG. When the power of the mobile phone is turned on, the first control unit 9 and the second control unit 10 start operating (S100). Normally, a standby screen is displayed on the mobile phone immediately after the power is turned on. Therefore, the display data selection unit 104 selects and outputs the display data output from the second control unit 10. The first control unit 9 is set so that the display data selection unit 104 selects display data output from the second control unit using a general-purpose port (S300). In this state, if the first control unit 9 does not transfer data to the second control unit 10 (No in S102), the first control unit 9 sets the data capture chip select signal 123 to disable. By doing so (S103), the gate unit 103 in the second control unit 10 is turned off so that data output from the data bus 121 of the first control unit 9 is not transmitted to the second control unit 10. (S104). Accordingly, for example, even when the first control unit transmits and receives data to and from the memory A81 connected to the data bus 121 of the first control unit 9 (S105), the High / Low change of the data bus 121 is not changed. The internal circuit 102, the input buffer, and the like in the second control unit 10 are operated extra, and it is possible to suppress unnecessary current.
[0038]
In this case, when the first control unit 9 transmits and receives data to and from the data bus 121 of the first control unit 9, for example, the memory A81, the second control unit 10 transitions to the standby state. Or an application or the like may be running. It suffices that data transmission and reception do not occur between the first control unit 9 and the second control unit 10 and the respective units operate independently.
[0039]
Next, when the first controller 9 transfers data to the second controller 10 (Yes in S102), the first controller 9 sets the data capture chip select signal 123 to enable. (S106), the gate circuit 103 in the second control unit 10 is turned on so that data output from the data bus 121 of the first control unit 9 is transmitted to the second control unit 10 (S107). ).
[0040]
In a state where the second control unit 10 is executing the multimedia-related application, the second control unit 10 cannot naturally transition to the standby state (No in S108). Therefore, data such as still images / moving images and text characters required for multimedia-related applications are generated by the CPU unit 101 of the second control unit 10 and displayed by the data output signal A124 output from the CPU unit 101. The data is output to the data selection unit 104. Since the display data selection unit 104 is set in advance by the general-purpose port of the first control unit 9 so that the display data output from the second control unit 10 is selected and output, the second control The display data output from the unit 10 is selected, the display data is output to the display unit 6 via the data bus 122 of the second control unit 10 (S109), and the data is displayed (S110). In this state, the first control unit 9 transmits and receives data to and from the internal circuit 102 of the second control unit 10 (S111).
[0041]
Further, when all the application processing in the second control unit 10 is completed and only the standby screen is displayed, the mobile phone generally uses the standby mode in the low power consumption mode in order to improve the battery life. Transition to the state (Yes in S108). When the second control unit 10 transitions to the standby state, the screen display by the second control unit 10 is not performed, and thus the output source of the display data to the display unit 6 is the first control unit 10 from the second control unit 10. It moves to the part 9. Therefore, the first control unit 9 changes the setting so that the display data selection unit 104 selects and outputs the display data output from the first control unit using the general-purpose port (S301). As a result, the display data output from the data bus 121 of the first control unit 9 is input to the second control unit 10 via the connection terminal 105 of the second control unit 10, and the previously set data The data is sent to the display data selection unit 104 via the gate unit 103 turned on by the enable setting of the capture chip select signal 123. The display data selection unit 104 selects the display data output from the first control unit 9 and outputs the display data to the display unit 6 via the data bus 122 of the second control unit 10 (S113). Is displayed (S110).
[0042]
If the second control unit 10 remains in the standby state (No in S114), no data is sent from the second control unit 10, so the process returns to S113 and the first control unit 9 The output display data is output to the display unit 6 to continue the display, and when the standby state is released (Yes in S114), the process returns to S101 and the display data of the display data selection unit 104 is temporarily controlled by the second control. Switching to the unit 10 side, and the same processing is performed thereafter.
[0043]
So far, various methods have been described for the on / off switching method of the gate unit 103 and the data selection switching method of the display data selection unit 104. However, these methods can be used individually or in combination. Similar effects can be obtained.
[0044]
A fourth embodiment of the present invention will be described. A block diagram showing a third embodiment of the present invention is the same as that of FIG.
[0045]
Hereinafter, a fourth embodiment of the present invention will be described with reference to the flowchart of FIG. When the power of the mobile phone is turned on and the first control unit 9 and the second control unit 10 start operating (S100), the second control unit 10 transitions to the standby state (Yes in S108). Until this is the same as in the first embodiment, the description is omitted.
[0046]
When all the application processing in the second control unit 10 is completed and only the standby screen is displayed, the mobile phone generally enters a standby state which is a low power consumption mode in order to improve battery life. Transition is made (Yes in S108). When the second control unit 10 shifts to the standby state, the screen display by the second control unit 10 is not performed, and therefore, the output source of the display data to the display unit 6 is the first control unit 10 from the second control unit 10. It moves to the part 9. Therefore, the second control unit 10 manually changes the setting by the second control unit 10 so that the display data selection unit 104 selects the display data input from the first control unit 9, and changes the setting. Later, the state transits to the standby state (S400). As a result, the display data output from the data bus 121 of the first control unit 9 is input to the second control unit 10 via the connection terminal 105 of the second control unit 10, and the previously set data The data is sent to the display data selection unit 104 via the gate unit 103 turned on by the enable setting of the capture chip select signal 123. The display data selection unit 104 selects the display data output from the first control unit 9 and outputs the display data to the display unit 6 via the data bus 122 of the second control unit 10 (S113). Is displayed (S110).
[0047]
If the second control unit 10 remains in the standby state (No in S114), no data is sent from the second control unit 10, so the process returns to S113 and the first control unit 9 The output display data is output to the display unit 6 to continue the display, and when the standby state is released (Yes in S114), the process returns to S101, and the second control unit 10 returns to the display data selection unit 104. The display data is switched to the second control unit 10, and the same processing is performed thereafter.
[0048]
According to the present invention, even when two control means perform display on one display means, it is possible to prevent a display error caused by writing display data to the display means at the same time.
[0049]
As described above, in the embodiments described above, it is possible to prevent display errors and extend the standby time and the call time of the portable terminal device.
[0050]
Further, a change in the signal of the data bus 121 of the first control unit 9 does not unnecessarily operate the input buffer and the internal circuit of the second control unit 10, thereby reducing the drive capability of the data bus 121. Therefore, the effect of suppressing the occurrence of high-frequency noise that occurs during the operation of the data bus 121 and affects the wireless communication unit 2 can be expected.
[0051]
In addition, the signal control circuit having the first control unit and the second control unit described in the above embodiments can be applied to a device including two or more control units other than the mobile terminal device. . As a result, the power consumption is reduced, and the change in the signal on the data bus 121 of the first control unit 9 does not unnecessarily operate the input buffer and the internal circuit of the second control unit 10, thereby eliminating the need for the data bus. Since the drive capability of the data bus 121 can be reduced, an effect of suppressing the generation of high-frequency noise which occurs during the operation of the data bus 121 and affects other circuits can be expected.
[0052]
【The invention's effect】
According to the present invention, even when two control means perform display on one display means, it is possible to prevent a display error caused by writing display data to the display means at the same time.
[0053]
Further, since it is possible to prevent useless current in the input buffer and the internal circuit, it is possible to extend the standby time and the talk time of the portable terminal device.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a first embodiment of a portable terminal device and a low power consumption unit used therein according to the present invention.
FIG. 2 is an example of a flowchart of a first embodiment of the portable terminal device and the low power consumption unit used therein according to the present invention.
FIG. 3 is a configuration diagram of a second embodiment of a portable terminal device according to the present invention and a low power consumption unit used therein.
FIG. 4 is an example of a flowchart of a second embodiment of the portable terminal device according to the present invention and the low power consumption unit used therein.
FIG. 5 is an example of an operation state of a gate circuit according to a second embodiment of the portable terminal device and the low power consumption unit used therein according to the present invention.
FIG. 6 is a configuration diagram of a portable terminal device according to a third embodiment of the present invention and a low power consumption unit used therein.
FIG. 7 is an example of a flowchart of a third embodiment of the portable terminal device and the low power consumption unit used therein according to the present invention.
FIG. 8 is an example of a flowchart of a fourth embodiment of a portable terminal device and a low power consumption unit used for the same according to the present invention.
FIG. 9 is a configuration diagram of a conventional example of a wireless communication device according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Antenna, 2 ... Wireless communication part, 3 ... Code decoding processing part, 4 ... Microphone, 5 ... Receiver, 6 ... Display part, 7 ... Input part, 8 ... Conventional memory part, 9 ... First control part Reference numeral 10: second control unit, 50: conventional control unit, 51: conventional portable game control unit, 52: first display unit of the conventional example, 53: second display unit of the conventional example 54: Conventional open / closed state detection unit, 81: Memory A, 82: Memory B, 101: CPU unit of the second control unit, 102: Internal circuit of the second control unit, 103: Gate unit, 104: Display Data selection unit, 105: connection terminal, 121: data bus of first control unit, 122: data bus of second control unit, 123: chip select signal for taking in data, 124: data output signal A, 125: data Output signal B, 126 ... chip select signal for peripheral device, 27 ... display data selection instruction signal, 128 ... display data selection section instruction signal

Claims (10)

In a portable terminal device having an antenna for transmitting / receiving a radio signal, a display unit for displaying an image, a first control unit for controlling these, and a second control unit,
The second control means includes an arithmetic means for processing video information, a connection terminal for connecting a signal line from the first control means to transmit and receive various data, and Gate means for selecting whether or not to transmit an input signal output via a terminal unit to the inside by a control signal output from the first control means; and And display data selection means for selecting the display data output via the unit and the gate means and the display data processed and output by the arithmetic means,
A portable terminal device, wherein an image is displayed on the display unit based on the display data selected by the display data selection unit. The mobile terminal device according to claim 1,
When the first control means transmits / receives data to / from a circuit other than the second control means, the first control means transmits a control signal for controlling the gate means not to transmit the input signal to the inside. Terminal device. The mobile terminal device according to claim 2,
The display means displays an image based on display data processed and output by the arithmetic means when the first control means transmits and receives data to and from a circuit other than the second control means. Mobile terminal device. The mobile terminal device according to claim 1,
The second arithmetic means has an internal circuit,
The mobile terminal device according to claim 1, wherein the video information is input from the first control unit to the arithmetic unit via the connection terminal unit, the gate unit, and the internal circuit. The mobile terminal device according to claim 1,
The portable terminal device, wherein the gate unit is controlled by a general-purpose port output from the first control unit. The mobile terminal device according to claim 1,
The portable terminal device, wherein the gate unit is controlled by a chip select signal output from the first control unit. The mobile terminal device according to any one of claims 1 to 6,
The selection of the display data selection unit is controlled by the first control unit. The mobile terminal device according to any one of claims 1 to 7,
The portable terminal device, wherein selection of the display data selection unit is controlled according to an operation state of the second control unit. In a signal control circuit having a first control unit and a second control unit,
The second control means includes: an arithmetic means for processing information; a connection terminal unit for connecting a signal line from the first control means to transmit and receive various data; Gate means for selecting whether or not to transmit an input signal output through the unit to the inside by a control signal output from the first control means; and a connection terminal section from the first control means. And a data selecting means for selecting and outputting data output via the gate means and the data processed and output by the arithmetic means. The signal control circuit according to claim 9,
The first control means transmits a control signal for controlling the gate means not to transmit the input signal to the inside when transmitting / receiving data to / from a circuit other than the second control means. Control circuit.

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