JP6119779B2 - REPRODUCTION CONTROL DEVICE, REPRODUCTION DEVICE, REPRODUCTION CONTROL METHOD, AND RECORDING MEDIUM - Google Patents

Description

  The present invention relates to a playback control device, a playback device including the playback control device, a playback control method, and a recording medium. For example, the present invention relates to a setting switching method for a data playback device operating on a battery and a setting switching device operating on a battery.

For example, some portable playback devices such as mobile phones and PDAs (Personal Digital Assistants) detect the orientation of the playback device and automatically switch the orientation of the image displayed on the display according to the detected orientation. is there.
The switching of the orientation of the image displayed on the display is realized by rewriting the display memory in the portable playback device.
In the portable playback device described above, the orientation of the image displayed on the display is constantly switched.

JP-A-11-196297

  However, in the above-described conventional portable playback device, the orientation of the image is always switched according to the change in the attitude of the portable playback device. There is a problem that is large.

  In order to solve the above-described problems of the prior art, the present invention can control the orientation of an image according to the orientation of the playback device, and can further reduce power consumption compared to the conventional playback control device, screen control method, An object is to provide a recording medium storing the program.

According to the present invention, it has a control means for switching the display direction of the display on the playback device based on the detection result of the posture detection means mounted on the playback device to detect the posture of the playback device,
The control means includes
When the restriction function for restricting the operation of the playback device is not released, the standby screen is displayed, the display direction of the standby screen is not switched regardless of the orientation of the playback device, and the restriction function is In response to the release operation, the menu screen is switched from the standby screen, the display direction of the display is switched based on the detection result of the attitude of the playback device, and the display direction is switched from the standby screen to the menu screen. Display on the menu screen in which the display direction is switched based on the detection result of the posture detection means after the standby screen is not switched.
A playback control device is provided.
According to the present invention, there is also provided a playback device that performs the above processing.

Further, according to the present invention, there is provided a control method for switching a display direction of display in the playback device based on a detection result of a posture detection unit that is mounted on the playback device and detects the posture of the playback device.
In the control method, when the restriction function for restricting the operation of the playback device is not released, the standby screen is displayed and the display direction of the standby screen display is not switched regardless of the orientation of the playback device. In addition, the menu screen is switched from the standby screen in response to the release operation of the restriction function, the display direction of the display is switched based on the detection result of the attitude of the playback device, and the standby screen is switched to the menu screen. When the display screen is not switched, after the standby screen is finished, the display is performed on the menu screen in which the display direction is switched based on the detection result of the posture detection means.
A control method for switching the display direction is provided.

  According to the present invention, a playback control device that can control the orientation of an image according to the orientation of the playback device and that can reduce power consumption compared to the prior art, a control method thereof, and a program for executing the control method are stored. Recording media can be provided.

FIG. 1 is an overall configuration diagram of a portable audio player according to an embodiment of the present invention. FIG. 2 is a configuration diagram of the front side of the portable audio player shown in FIG. FIG. 3 is a diagram in which X, Y, and Z axes are defined with reference to coordinate axes of relative coordinates based on the portable audio player shown in FIG. FIG. 4 is a diagram for explaining a cross key and operation keys on the front side of the portable audio player shown in FIG. FIG. 5 is a diagram for explaining the posture of the portable audio player shown in FIG. FIG. 6 is a diagram showing the relationship between the attitude of the portable audio player shown in FIG. 1 and the image data displayed on the display. FIG. 7 is a diagram exemplifying a case where the function is switched by assigning the definition of the operation key of the cross key in accordance with the switching of the screen displayed on the display of the portable audio player shown in FIG. FIG. 8 is a flowchart for explaining an operation example when the power source of the portable audio player shown in FIG. 1 is switched from on to off. FIG. 9 is a flowchart for explaining an operation example when the portable audio player shown in FIG. 1 falls. FIG. 10 is a flowchart for explaining processing by the control circuit when detecting the attitude of the portable audio player shown in FIG. FIG. 11 is a flowchart for explaining screen orientation switching processing in the portable audio player shown in FIG. FIG. 12 is a flowchart for explaining screen orientation switching processing in the portable audio player shown in FIG. FIG. 13 is a flowchart for explaining screen orientation switching processing in the portable audio player shown in FIG.

Hereinafter, a portable audio player according to an embodiment of a playback apparatus having the playback control apparatus of the present invention will be described.
<First Embodiment>
First, the correspondence between the components of the present embodiment and the components of the present invention will be described.
A display 23 shown in FIG. 1 is a display of the present invention.
The processing circuit 33 shown in FIG. 1 is the posture detection means of the present invention.
The control circuit 47 shown in FIG. 1 is the control means of the present invention.
The operation key 41 shown in FIG. 1 is the operation means of the present invention.
The program RPG shown in FIG. 1 is the program of the present invention.
A memory 45 shown in FIG. 1 is a recording medium of the present invention. The recording medium of the present invention is a semiconductor memory, an optical disk, a magneto-optical disk, a magnetic disk, or the like.
Step ST11 shown in FIG. 8 is the first step or the first procedure of the present invention.
Further, step ST14 shown in FIG. 8 is the second step or the second procedure of the present invention.
Steps ST15 and ST17 shown in FIG. 8 are the third step or the third procedure of the present invention.

FIG. 1 is an overall configuration diagram of a portable audio player 1 according to an embodiment of the present invention. As shown in FIG. 1, the portable audio player 1 includes, for example, a recording disk drive 11, a reproduction processing circuit 16, an audio output unit 17, a headphone terminal 18, a display memory 21, a display 23, an acceleration sensor and a gravitational acceleration sensor 31, It has a processing circuit 33, operation keys 41, a power supply circuit 48, a memory 45, and a control circuit 47.
Each component shown in FIG. 1 is accommodated in a thin plate-shaped casing 51, for example, as shown in FIG.

[Recording disk drive 11]
The recording disk drive 11 is, for example, a hard disk drive (Hard Disk Drive (HDD)), and includes a recording disk 13, a head 14, and a head retracting unit 15.
The recording disk 13 is, for example, a magnetic disk. The recording disk 13 records music data, accompanying data such as artist names and album names attached to the music data, music management data such as a playlist for managing the music data, recording management data for managing the recording data, and the like. .
The head 14 reads out music data from the recording disk 13 and outputs it to the reproduction processing circuit 16.
The head 14 is held by the head retracting unit 15 in a state where the recording disk 13 is not accessed. In the head retracting section 15, the head 14 is fixed and held, so that even if an impact is applied to the portable audio player 1, the head 14 does not damage the recording area of the recording disk 13.
When the recording disk 13 is accessed, the head 14 is released from the fixed state and moves from the head retracting portion 15 toward the recording disk 13.
The head 14 reads out music data, accompanying data, music management data, recording management data, and the like from a specified address in the recording disk 13 based on the control of the control circuit 47 and outputs the data to the reproduction processing circuit 16.

[Reproduction processing circuit 16]
The reproduction processing circuit 16 writes the music data read from the recording disk 13 by the head 14 to the buffer memory BUF, reads the music data from the buffer memory BUF, performs reproduction processing, and outputs a reproduction signal to the audio output unit 17.
In addition, the reproduction processing circuit 16 outputs information necessary for reproducing the music other than the music data to be output, such as accompanying data, music management data, and recording management data, to the control circuit 47.
[Audio output unit 17]
The audio output unit 17 amplifies the reproduction signal output from the reproduction processing circuit 16 and outputs it to the headphones via the headphone terminal 18 shown in FIG.

[Display memory 21]
The display memory 21 is a memory that stores image data corresponding to the screen displayed on the display 23. Image data is written into the display memory 21 by the control circuit 47. Data written to the display memory 21 is output to the display 23.
[Display 23]
The display 23 is a liquid crystal display or an organic EL display (Organic electro
luminescence) and the like, and the image data written in the display memory 21 is displayed.

[Display unit 24]
The display unit 24 is a module having the functions of the display memory 21 and the display 23.

[Operation key 41]
For example, as shown in FIG. 2, FIG. 3, FIG. 4, etc., the operation key 41 includes a cross key K1, a SEARCH / MENU key K2, a stop key K3, a volume increase key K4, a volume decrease key K5, a HOLD key K20, a power source. Key K21 or the like.
The cross key K1 includes operation keys K10, K11, K12, K13, and K14.
As shown in FIG. 3, relative coordinates X, Y, and Z with respect to the portable audio player 1 are defined for the portable audio player 1. Considering the relative coordinates based on the portable audio player 1, the cross key K1 has any of K11, K12, K13, and K14 in the + Z, -X, -Z, and + X directions with respect to the operation key K10. Configured to be located.
Similarly, when considering relative coordinates based on the portable audio player 1, the operation key 41 is provided in the −Z direction with respect to the display 23.

[Acceleration sensor and gravity acceleration sensor 31]
As shown in FIG. 3, the portable audio player 1 is defined with X, Y, and Z axes as relative coordinate axes with respect to the portable audio player 1. The origin of the relative coordinates and the center of the display surface of the display 23 are defined so as to coincide with each other when viewed from the Y axis. The acceleration sensor and the gravitational acceleration sensor 31 detect accelerations in the X, Y, and Z directions on the X, Y, and Z axes, and an acceleration signal A_X that indicates acceleration in the X direction and an acceleration signal A_Y that indicates acceleration in the Y direction , An acceleration signal A_Z indicating the acceleration in the Z direction is output to the processing circuit 33. In particular, when acceleration is not received due to factors other than gravity, the acceleration signals A_X, A_Y, and A_Z in the X, Y, and Z directions are added to obtain a gravitational acceleration signal A_G based on gravitational acceleration.
The direction of the gravitational acceleration changes at any time according to the inclination of the portable audio player 1 in the relative coordinates X, Y, Z in the portable audio player 1 shown in FIG. However, as shown in FIG. 4, when the absolute coordinates X0 and Z0 axes are defined with reference to the direction of gravity, the direction of gravitational acceleration can always be the -Z0 direction on the Z0 axis which is the coordinate axis of the absolute coordinates. .

[Processing circuit 33]
The processing circuit 33 performs a drop detection process and a posture detection process of the portable audio player 1 based on the acceleration signals A_X, A_Y, and A_Z output from the acceleration sensor and the gravitational acceleration sensor 31. The processing circuit 33 determines that the portable audio player 1 has fallen when the acceleration signals A_X, A_Y, and A_Z input from the acceleration sensor and the gravitational acceleration sensor 31 satisfy the set conditions, and outputs a drop detection signal S33a. Output to the control circuit 47.

  Various methods for determining fall using the acceleration signals A_X, A_Y, and A_Z are conceivable. For example, when the acceleration sensor and the gravitational acceleration sensor 31 are located at the center of gravity of the portable audio player 1, when the combined signal of the acceleration signals A_X, A_Y, and A_Z indicates “0”, the portable audio player There is also a method of determining that 1 has fallen, and in the present invention, this is taken as an example (embodiment).

Further, the processing circuit 33 determines whether the attitude of the portable audio player 1 is one of the attitudes STATE1, STATE2, and STATE3 shown in FIGS. 5A to 5C based on the acceleration signals A_X, A_Y, and A_Z. To detect.
As described above, the sum of the acceleration signals A_X, A_Y, and A_Z becomes the gravitational acceleration signal A_G based on the gravitational acceleration when no acceleration is received due to factors other than gravity. Since the gravitational acceleration direction coincides with the −Z0 direction, it is possible to determine how much the relative coordinate axis of the portable audio player 1 is inclined with respect to the absolute coordinate axis based on the gravitational acceleration direction. Based on this inclination, the control means detects whether the attitude of the portable audio player 1 is any one of the attitudes STATE1, STATE2, and STATE3 shown in FIGS.

Here, as shown in FIGS. 5 (A) and 5 (D), the posture STATE 1 has an X axis that is a relative coordinate axis of the portable audio player 1 with respect to an X 0 axis that is an absolute coordinate axis based on the gravitational acceleration direction. This is the posture of the portable audio player 1 when it is tilted by ± 60 °. That is, the display 23 is in the + Z0 direction with respect to the operation keys K1, K2, K3, K4, and K5.
In addition, as shown in FIGS. 5B and 5D, the posture STATE2 is 60 relative to the X0 axis, which is the absolute coordinate axis with respect to the gravitational acceleration direction. This is the posture of the portable audio player 1 when intersecting at an angle of 180 °. That is, the display 23 is in the + X0 direction with respect to the operation keys K1, K2, K3, K4, and K5.
In addition, as shown in FIGS. 5C and 5D, the posture STATE3 has an X0 axis, which is an absolute coordinate axis based on the gravitational acceleration direction, of the X axis that is a relative coordinate axis of the portable audio player 1 is 180 ° to This is the posture of the portable audio player 1 when intersecting at 300 °. That is, the display 23 is positioned in the −X0 direction with respect to the operation keys K1, K2, K3, K4, and K5.

When it is detected whether the positional relationship between the display 23 of the portable audio player 1 and the operation keys K1, K2, K3, K4, and K5 is STATE1, STATE2, or STATE3, the Y axis of the portable audio player 1 Directional components are not required. That is, the positional relationship between the display 23 of the portable audio player 1 and the operation keys K 1, K 2, K 3, K 4, and K 5 on the X 0 and Z 0 axes, which are absolute coordinate axes, is relative to the relative coordinate axes X, It depends only on the Z axis. Therefore, the processing circuit 33 detects the posture of the portable audio player 1 using only the acceleration signals A_X and A_Z.
For this reason, when performing the control as described above, a biaxial acceleration sensor may be used as the acceleration sensor and the gravitational acceleration sensor 31 instead of the triaxial acceleration sensor.
Based on the attitude detected in this way, the processing circuit 33 outputs to the control circuit 47 an attitude detection signal S33b indicating which of the detected attitude is STATE1, STATE2, or STATE3. For example, the processing circuit 33 outputs a number such as 1 for STATE 1 and 2 for STATE 2 to the control circuit 47.

[Attitude detection unit 34]
The posture detection unit 34 is a module having an acceleration sensor and gravity acceleration sensor 31 and a posture detection function in the processing circuit 33.

[Fall detection unit 35]
The drop detection unit 35 is a module having an acceleration sensor and gravity acceleration sensor 31 and a drop detection function in the processing circuit 33.

[Battery 43]
The battery 43 supplies power to the portable audio player 1.

[Power circuit 48]
When a power-on instruction is input from the control circuit 47, the power supply circuit 48 is supplied with power from the battery 43, performs necessary voltage conversion for the portable audio player 1, and then each component of the portable audio player 1. When power is supplied to the control circuit 47 and a power-off instruction is input from the control circuit 47, the power supply is stopped.

[Memory 45]
The memory 45 includes a ROM and a RAM. The ROM stores non-rewritable PRG and fixed data, and the RAM stores data temporarily stored for work.

[Control circuit 47]
The control circuit 47 executes the program PRG read from the RAM of the memory 45 and controls the operation of the portable audio player 1 defined in the present embodiment.
When the drop detection signal S33a is input from the processing circuit 33, the control circuit 47 controls the recording disk drive 11 so that the head 14 is retracted to the head retracting portion 15.
In addition, when the power of the portable audio player 1 is switched from OFF to ON, the control circuit 47 displays an image in a direction corresponding to the attitude of the portable audio player 1 indicated by the attitude detection signal S33b from the processing circuit 33. The image data stored in the display memory 21 is rewritten so as to be displayed on the screen.

6A, FIG. 6B, FIG. 6C, and FIG. 6D show the relationship between the posture of the portable audio player 1 indicated by the posture detection signal S33b and the image data displayed on the display 23. Show. FIG. 6D shows a state in which the letters A and B are displayed in the −X0 · + Z0 area and the + X0 · −Z0 area of the display 23 in absolute coordinates based on the gravitational acceleration direction. The control circuit 47 ensures that the letters A and B are always displayed on the display 23 in the same area regardless of the attitude of the portable audio player 1 when considered from absolute coordinates based on gravitational acceleration. It is controlled.
In contrast, FIGS. 6 (A), 6 (B), and 6 (C) show that when the portable audio player 1 is in the STATE 1, STATE 2, and STATE 3, respectively, A and B are portable audio. FIG. 3 is a diagram showing where the player 1 is displayed in relative coordinates. The relative coordinates X and Z axes with reference to the portable audio player 1 are the same axes as the X and Z axes shown in FIGS. 3 and 5A to 5C. In absolute coordinates based on the gravitational acceleration direction, the characters displayed as A in the −X0 / + Z0 direction and B in the + X0 / −Z0 direction of the display 23 are as follows in the relative coordinates of the portable audio player 1 respectively. Will be displayed in the coordinate area.

In the case of STATE1, A is displayed in the −X · + Z area, and B is displayed in the + X · −Z area.
In the case of STATE2, A is displayed in the −X · −Z area and B is displayed in the + X · + Z area.
In the case of STATE3, A is displayed in the + X · + Z area, and B is displayed in the −X · −Z area.

  As described above, the image data displayed on the portable audio player 1 is processed by the control circuit 47 so that the coordinate area of the absolute coordinate does not change when the absolute coordinate is considered. The image data displayed on the display 23 is displayed by an innumerable set of dots. The control circuit 47 performs coordinate conversion of coordinates representing dot positions in relative coordinates with respect to the portable audio player 1. At this time, the processing of the image data is performed so that the orientation of characters and images viewed from the absolute coordinates based on the gravitational acceleration direction is not changed. Such work such as dot coordinate conversion consumes a large amount of power because it requires CPU power (power supplied to the CPU). In this manner, the control circuit 47 processes the image data so that the orientation corresponds to the orientation of the portable audio player 1 indicated by the orientation detection signal S33b.

In the present embodiment, at the stage of storing the image data displayed on the display 23 in the display memory 21, the control circuit 47 causes the image data to be oriented in the direction corresponding to the attitude of the portable audio player 1 indicated by the attitude detection signal S33b. Is being processed. In this way, it is possible to switch the image displayed on the display 23 to a direction corresponding to the posture of the portable audio player 1 indicated by the posture detection signal S33b.
In addition to such a configuration, for example, the display memory 21 can have image data processing capability. In such a case, the display memory 21 processes the image data so that the image is displayed on the display 23 in a direction corresponding to the posture of the portable audio player 1 indicated by the posture detection signal S33b. When the display memory 21 processes the image data, the image displayed on the display 23 can be switched to a direction corresponding to the attitude of the portable audio player 1 indicated by the attitude detection signal S33b. Further, when the display memory 21 processes the image data, the image data is processed in advance in a direction corresponding to the orientation of the portable audio player 1 indicated by the orientation detection signal S33b, and the processed image data is stored. The image data may be output to the display 23, or the image data may be output to the display 23 while processing the image data.

Further, the control circuit 47 switches the definition assigned to the operation keys K11, K12, K13, and K14 of the cross key K1 according to the attitude indicated by the attitude detection signal S33b, so that the functions of the operation keys K11, K12, K13, and K14 are changed. Switch.
Further, when the posture detection signal S33b indicates the posture STATE1, the control circuit 47 assigns a definition to the operation keys K11, K12, K13, and K14 of the cross key K1, as shown in FIG.
Further, when the posture detection signal S33b indicates the posture STATE2, the control circuit 47 assigns a definition to the operation keys K11, K12, K13, and K14 of the cross key K1, as shown in FIG. 7B.
Further, when the posture detection signal S33b indicates the posture STATE3, the control circuit 47 assigns the definition to the operation keys K11, K12, K13, and K14 of the cross key K1 as shown in FIG. 7C.
As shown in FIGS. 7A to 7C, the control circuit 47 assigns definitions to the operation keys K11, K12, K13, and K14 in accordance with the attitude of the portable audio player 1, so that the operation keys K11, Switches the functions of K12, K13, and K14. Thus, even if the screen orientation is switched, the operation keys arranged in the + X0 direction, the −X0 direction, the + Z0 direction, and the −Z0 direction with respect to the gravitational acceleration direction always have the same function. Therefore, even when the screen is switched, the user can operate the portable audio player 1 without being confused.
Note that the definition lists shown in FIGS. 7A to 7C may be stored in advance in the RAM of the memory 45, for example, or the portable audio player 1 when switching the definition of the operation keys. It may be generated by the control circuit 47 on the basis of the attitude and stored in the ROM of the memory 45.

  In the portable audio player 1, all or part of the functions of the processing circuit 33 and the control circuit 47 may be realized as an electronic circuit, or the central processing unit (CPU) executes the program PRG read from the memory 21. May be realized.

Hereinafter, an operation example of the portable audio player 1 will be described.
[First operation example]
Hereinafter, an operation example when the power source of the portable audio player 1 is switched from OFF to ON will be described.
FIG. 8 is a flowchart for explaining the operation example.

Step ST11:
Based on the operation signal from the operation key 41, the control circuit 47 determines whether or not an instruction to switch the power supply circuit 48 of the portable audio player 1 from OFF to ON is input. Proceed to ST12.

Step ST12:
The control circuit 47 switches the power supply circuit 48 from off to on.
In addition, the control circuit 47 writes initial animation image data upon power-on in the display memory 21 in a predetermined direction. As a result, when the processes of steps ST12, ST13, ST14, ST15, and ST16 are being performed, an animation image is displayed on the display 23.

Step ST13:
Thereby, power supply from the power supply circuit 48 to the acceleration sensor and the gravitational acceleration sensor 31 is started, and the acceleration sensor and the gravitational acceleration sensor 31 start an initial setting operation.

Step ST14:
After completion of the initial setting operation, the acceleration sensor and the gravitational acceleration sensor 31 detect accelerations in the X, Y, and Z directions. The acceleration signal A_X indicating the acceleration in the X direction, the acceleration signal A_Y indicating the acceleration in the Y direction, and Z An acceleration signal A_Z indicating the acceleration in the direction is output to the processing circuit 33. Based on the acceleration signals A_X and A_Z, the processing circuit 33 determines the posture of the portable audio player 1 from the postures STATE1, STATE2, and STATE3 shown in FIGS. 5 (A) to (C) and FIGS. 6 (A) to (C). It is detected which one is.
The processing circuit 33 outputs an attitude detection signal S33b indicating the detected attitude to the control circuit 47.

Step ST15:
The control circuit 47 repeatedly detects the posture in step ST14 several times to determine whether the posture detected in step ST14 is held for a predetermined period. If it is determined that the posture is held, Proceed to step ST16. If it is determined that the posture has been changed, the process returns to step ST14 again to continue detecting the posture of the portable audio player 1. In this embodiment, it is determined whether or not the posture of the portable audio player 1 is held by repeating the detection of the posture several times. For example, after detecting the posture of the portable audio player 1 once, a predetermined period of time is detected. Later, the posture of the portable audio player 1 may be detected again, and if the two detection results do not change, it may be determined that the posture of the portable audio player 1 is maintained.

Step ST16:
As shown in FIGS. 5 (A) to 5 (C) and FIGS. 6 (A) to (C), the control circuit 47 is a portable audio player 1 indicated by the attitude detection signal S33b input from the processing circuit 33 in step ST13. to identify the display of the direction corresponding to the posture.

Step ST17:
The control circuit 47 erases the animation image data written in the display memory 21 and ends the display of the animation image displayed on the display 23.

Step ST18:
As shown in FIGS. 5A to 5C and FIGS. 6A to 6C, the control circuit 47 corresponds to the attitude of the portable audio player 1 indicated by the attitude detection signal S33b input in step ST13. The image data of the menu screen is written into the display memory 21 so that the menu screen is displayed in the direction to be displayed.
Thereby, a menu screen is displayed on the display 23 following the animation image.

Step ST19:
The control circuit 47 defines the operation keys K11, K12, K13, and K14 in accordance with the postures STATE1, STATE2, and STATE3 of the portable audio player 1 indicated by the posture detection signal S33b input from the processing circuit 33 as shown in FIG. By assigning them as shown in A) to (C), the functions of the operation keys K11, K12, K13, and K14 are switched.
Thereafter, the processing circuit 33 performs only the drop detection of the portable audio player 1 until the power of the portable audio player 1 is next switched from off to on.
Various methods for controlling the portable audio player 1 so as not to detect the posture are conceivable. For example, the control circuit 47 controls so that the processing circuit 33 does not perform the posture detection processing of the portable audio player 1, and the posture detection that is the detection result of the processing circuit 33 that performs the posture detection processing of the portable audio player 1 In the method of not outputting the signal S33b to the control circuit 47, the processing circuit 33 performs the posture detection processing of the portable audio player 1 and outputs the posture detection signal S33b as a detection result. The control circuit 47 outputs the posture detection signal S33b. There is a method of not receiving. In terms of reducing power consumption, the control circuit 47 is best controlled not to perform the posture detection process in the processing circuit 33.

Generally, in the portable audio player 1 or the like, a part of the display memory 21 is always rewritten, for example, by scrolling the index where the cursor is located. However, in the present invention, in particular, the power consumption can be significantly suppressed by performing the process of having to rewrite the display memory 21 to rotate the image displayed on the display 23 only when the power is turned on. The portable audio player 1 operates by supplying power from the battery 43, and power consumption must be suppressed as much as possible in order to be able to reproduce a longer operation period . When considering user benefits, it is necessary to minimize the number of processings that require CPU power (power for operation of the CPU), and the present invention is also effective for such players operating on batteries.

[Second operation example]
Hereinafter, an operation example when the portable audio player 1 falls will be described.
FIG. 9 is a flowchart for explaining the operation example.

Step ST21:
The processing circuit 33 determines whether or not the portable audio player 1 has fallen based on the acceleration signals A_X, A_Y, and A_Z input from the acceleration sensor and the gravitational acceleration sensor 31. move on.

Step ST22:
The processing circuit 33 outputs the fall detection signal S33a to the control circuit 47 based on the determination in step ST21.

Step ST23:
When the drop detection signal S33a is input from the processing circuit 33, the control circuit 47 controls the recording disk drive 11 so that the head 14 is retracted to the head retracting portion 15.

As described above, according to the portable audio player 1 in the present embodiment, the posture of the portable audio player 1 is detected on condition that the power of the portable audio player 1 is switched from off to on. The orientation of the portable audio player 1 is not detected under the conditions other than displaying the menu screen on the display 23 in the direction corresponding to that and switching the power of the portable audio player 1 from off to on.
Therefore, according to the portable audio player 1, the number of times of switching the orientation of the screen displayed on the display 23 is significantly reduced compared to the conventional case, and power saving can be achieved.
Particularly when the user uses the portable audio player 1 while walking in a bag or the like, power saving can be achieved as compared with the conventional case.

Second Embodiment
This embodiment is different from the first embodiment described above only in processing by the control circuit 47 when detecting the attitude of the portable audio player 1. FIG. 10 is a diagram illustrating this embodiment. In step ST34 of FIG. 10, the control circuit 47 determines whether or not the posture of the portable audio player 1 is detected by the posture detection. If the posture is detected, the process proceeds to step ST35. When the posture is not detected, for example, when the portable audio player 1 is always turned, the process proceeds to step ST39. In step ST39, the control circuit 47 displays the menu screen in the direction of the display screen at the end of the previous time.
Since other parts have been described in the first embodiment, they are omitted here.

<Third Embodiment>
In the embodiment described above, a screen in an orientation corresponding to the attitude of the portable audio player 1 on condition that the power of the portable audio player 1 is switched from OFF to ON as in step ST11 shown in FIG. The case of displaying is illustrated.
In contrast, in the present embodiment, the display on the display 23 in the portable audio player 1 is oriented in accordance with the attitude of the portable audio player 1 on condition that the screen saver screen is switched to the normal menu screen. Display the screen.
FIG. 11 is a flowchart for explaining screen orientation switching processing in the portable audio player 1 of the present embodiment.

Step ST41:
The control circuit 47 of the portable audio player 1 performs control so that the menu screen is displayed on the display 23 using the image data of the menu screen stored in the display memory 21.

Step ST42:
The control circuit 47 of the portable audio player 1 determines whether or not the operation of the portable audio player 1 has been performed during a predetermined period. If no operation is performed for a predetermined period, the process proceeds to step ST33.

Step ST48:
The control circuit 47 of the portable audio player 1 switches the screen displayed on the display 23 from a normal menu screen or the like to a screen saver screen when the portable audio player 1 is not operated for a predetermined period.

Step ST44:
The control circuit 47 of the portable audio player 1 monitors whether or not the portable audio player 1 has been operated. If an operation has been performed, the process proceeds to step ST45.

Step ST45:
The control circuit 47 of the portable audio player 1 controls the acceleration sensor and the gravitational acceleration sensor 41 so that the initial setting operation of the acceleration sensor and the gravitational acceleration sensor 31 is started.

Step ST46:
After completion of the initial setting operation, the acceleration sensor and the gravitational acceleration sensor 31 detect accelerations in the X, Y, and Z directions. The acceleration signal A_X indicating the acceleration in the X direction, the acceleration signal A_Y indicating the acceleration in the Y direction, and Z An acceleration signal A_Z indicating the acceleration in the direction is output to the processing circuit 33. Based on the acceleration signals A_X and A_Z, the processing circuit 33 determines the posture of the portable audio player 1 from the postures STATE1, STATE2, and STATE3 shown in FIGS. 5 (A) to (C) and FIGS. 6 (A) to (C). It is detected which one is.
The processing circuit 33 outputs an attitude detection signal S33b indicating the detected attitude to the control circuit 47.

Step ST47:
The control circuit 47 determines whether or not the posture detected in step ST46 is held for a predetermined period. If it is determined that the posture is held, the process proceeds to step ST48. If it is determined that the posture has been changed, the process returns to step ST46 again to detect the posture of the portable audio player 1.

Step ST48:
As shown in FIGS. 5 (A) to 5 (C) and FIGS. 6 (A) to 6 (C), the control circuit 47 is a portable audio player 1 indicated by the attitude detection signal S33b input from the processing circuit 33 in step ST36. to identify the display of the direction corresponding to the posture.

Step ST49:
The control circuit 47 erases the screen saver data written in the display memory 21 and ends the screen saver displayed on the display 23.

Step ST410:
As shown in FIGS. 5A to 5C and FIGS. 6A to 6C, the control circuit 47 is a portable audio player 1 indicated by the attitude detection signal S33b input to the control circuit 47 in step ST36. The image data of the menu screen is written in the display memory 21 so that the menu screen is displayed in the direction corresponding to the posture.
As a result, a menu screen is displayed on the display 23 following the screen saver.

Step ST411:
The control circuit 47 assigns the definitions of the operation keys K11, K12, K13, and K14 according to the postures STATE1, STATE2, and STATE3 of the portable audio player 1 indicated by the posture detection signal S33b input from the processing circuit 33. As shown in FIGS. 7A, 7B, and 7C, the functions of the operation keys K11, K12, K13, and K14 are switched by assigning the definitions of the operation keys K11, K12, K13, and K14.
Thereafter, the processing circuit 33 performs only the drop detection of the portable audio player 1 and does not detect the posture until the power of the portable audio player 1 is switched from OFF to ON.

<Fourth embodiment>
In the fourth embodiment, on the condition that the HOLD key K20 in the portable audio player 1 is released, the screen display is switched in the direction corresponding to the posture of the portable audio player 1.
FIG. 12 is a flowchart for explaining a screen orientation switching process in the portable audio player 1 of the present embodiment.

Step ST51:
The control circuit 47a of the portable audio player 1a determines whether or not the HOLD key K20 shown in FIG. 2 has been released. If it is determined that the HOLD key K20 has been released, the process proceeds to step ST52.

Step ST52:
Based on the attitude detection signal S33b from the processing circuit 33, the control circuit 47a determines that the attitude of the portable audio player 1 is the attitude STATE1 shown in FIGS. 5 (A) to (C) and FIGS. 6 (A) to (C). It is determined whether or not switching has occurred between STATE2 and STATE3. If it is determined that switching has occurred, the process proceeds to step ST53, and if not, the process returns to step ST51.

Step ST53:
The control circuit 47a switches the screen being displayed on the display 23 so that the screen is displayed in the direction corresponding to the attitude switched in step ST52.

  The portable audio player 1a may be added to the function described with reference to FIG. 8 in the first embodiment in addition to the function described with reference to FIG. 11, or may not have the function described with reference to FIG. May be.

<Fifth Embodiment>
In the fifth embodiment, the portable audio player 1 responds to the posture of the portable audio player 1 on condition that any one of the operation keys K11, K12, K13, and K14 in the portable audio player 1 is operated. The screen display is switched to the right direction and the function of the operation key is switched.
FIG. 13 is a flowchart for explaining the process of switching the screen orientation and the function of the operation key in the portable audio player 1 of the present embodiment.

Step ST61:
The control circuit 47 determines whether or not there is an input from the operation keys K11, K12, K13, and K14 of the portable audio player 1. If there is an input from the operation keys K11, K12, K13, K14, the process proceeds to step ST62.

Step ST62:
The control circuit 47 holds information indicating which operation key has been operated, for example, in the RAM of the memory 45.

Step ST63:
The control circuit 47 determines whether or not the input made in step ST61 is an input after a predetermined time has elapsed since the last input. When the predetermined period has elapsed, it can be determined that the user's consistent input operation has been completed. For this reason, when the input made in step ST61 has passed for a predetermined period since the last input last time, the input made in step ST61 is considered to be the start of a new input operation. In this case, the control circuit 47 determines that the display should be switched in accordance with the attitude of the portable audio player 1, and proceeds to step ST64.

Step ST64:
The control circuit 47 causes the acceleration sensor and the gravitational acceleration sensor 31 of the portable audio player 1 to start an initial setting operation.

Step ST65: After completing the initial setting operation, the acceleration sensor and the gravitational acceleration sensor 31 detect accelerations in the X, Y, and Z directions, and detect an acceleration signal A_X indicating acceleration in the X direction and an acceleration signal A_Y indicating acceleration in the Y direction. And an acceleration signal A_Z indicating the acceleration in the Z direction is output to the processing circuit 33.
Based on the acceleration signals A_X and A_Z, the processing circuit 33 determines the posture of the portable audio player 1 from the postures STATE1, STATE2, and STATE3 shown in FIGS. 5 (A) to (C) and FIGS. 6 (A) to (C). It is detected which one is.
The processing circuit 33 outputs an attitude detection signal S33b indicating the detected attitude to the control circuit 47.

Step ST66:
The control circuit 47 determines whether or not the posture detection signal S33b detected in step ST65 is held for a predetermined period. If it is determined that the posture detection signal S33b is held, the process proceeds to step ST67. If it is determined that the attitude detection signal S33b has been changed, the process returns to step ST65 to detect the attitude of the portable audio player 1.

Step ST67:
As shown in FIGS. 5 (A) to 5 (C) and FIGS. 6 (A) to (C), the control circuit 47 is a portable audio player 1 indicated by the attitude detection signal S33b output from the processing circuit 33 in step ST65. The display direction on the display unit corresponding to the posture is specified.

Step ST68:
The control circuit 47 writes the image data of the menu screen in the display memory 21 so that the menu screen is displayed in the specified direction.
As a result, a menu screen having an orientation corresponding to the posture of the portable audio player 1 is displayed on the display 23.

Step ST69:
The control circuit 47 is a definition list of operation keys K11, K12, K13, and K14 according to the postures STATE1, STATE2, and STATE3 of the portable audio player 1 indicated by the posture detection signal S33b input from the processing circuit 33. FIG. The functions of the operation keys K11, K12, K13, and K14 are switched by generating and assigning any one of (A) to (C).

Step ST610:
The control circuit 47 holds in step ST62 as information whether the operation key input in step ST61 is K11, K12, K13, or K14. In step ST70, the control circuit 47 executes the function assigned to the operation key held in step ST62. The functions of the operation keys K11, K12, K13, and K14 executed here are functions after the definition is assigned and the functions are switched in step ST69. For example, if the operation key input in step ST61 is K11, in step ST610, the definition of the operation keys K11, K12, K13, and K14 corresponding to the attitude of the portable audio player 1 is assigned. Perform the function.
When there are a plurality of inputs in step ST61, for example, if K11 and K12 are input, in step ST610, the functions of K11 and K12 after the definition is assigned are executed.

  Thereafter, the processing circuit 33 performs only the fall detection of the portable audio player 1 and does not detect the posture until the power of the portable audio player 1 is next switched from off to on.

The present invention is not limited to the embodiment described above.
That is, those skilled in the art may make various modifications, combinations, subcombinations, and alternatives regarding the components of the above-described embodiments within the technical scope of the present invention or an equivalent scope thereof.
For example, in the embodiment described above, as a reproducing apparatus including a reproduction control apparatus of the present invention has been illustrated is applied to a portable audio player, the playback device, a mobile phone, PDA, game consoles, radio etc. Others The present invention may be applied to a playback device, and the data to be played back may be content data such as music data, image data, and moving image data. In addition, the present invention can be applied to any apparatus that can reproduce data, and includes at least a display unit and an operation unit and is convenient to switch settings when the orientation of the apparatus body changes.

  In the above-described embodiment, the case where the acceleration sensor and the gravitational acceleration sensor 31 are used as the posture detection means of the present invention is illustrated. However, the metal sphere is a portable audio player 1 among a plurality of piezoelectric elements. A configuration may be adopted in which the posture of the portable audio player 1 is detected by contacting a piezoelectric element corresponding to the posture and electrically detecting the contact.

  In the embodiment described above, the function is assigned by assigning the definition of the operation keys K11, K12, K13, and K14 of the cross key K1 in accordance with the switching of the screen displayed on the display 23, as shown in FIGS. However, the functions of the SERCH / MENU key K2, the stop key K3, the volume increase key K4, and the volume decrease key K5 may be switched.

  Further, according to the present invention, the orientation of the image can be controlled according to the attitude of the playback device, and the power consumption can be suppressed as compared with the conventional case.

  Further, according to the present invention, the function of the operation key can be switched by switching the definition of the operation key according to the posture of the playback device, and the user can always operate the operation key in a certain direction based on the gravitational acceleration direction. Can always perform the same function.

  According to the present invention, the posture of the playback device is detected only under a predetermined condition, and the setting of the playback device is switched according to the detected posture of the playback device. For this reason, since unnecessary setting switching is not performed, power consumption can be suppressed as compared with the conventional case.

DESCRIPTION OF SYMBOLS 1 ... Portable music player, 11 ... Recording disk drive, 13 ... Recording disk, 15 ... Head evacuation part, 16 ... Playback processing circuit, 17 ... Audio output part, 18 ... Headphone terminal, 21 ... Display memory, 23 ... Display, DESCRIPTION OF SYMBOLS 24 ... Display part, 31 ... Acceleration sensor and gravitational acceleration sensor, 33 ... Processing circuit, 34 ... Attitude detection part, 35 ... Fall detection part, 41 ... Operation key, 43 ... Battery, 45 ... Memory, 47 ... Control circuit, 48 ... Power supply circuit

Claims (20)

Based on the detection result of the posture detection means for detecting the posture of the reproduction device mounted on the reproduction device, the control means for switching the display direction of the display in the reproduction device,
The control means includes
When the restriction function for restricting the operation of the playback device is not released, the standby screen is displayed, the display direction of the standby screen is not switched regardless of the orientation of the playback device, and the restriction function is In response to the release operation, the menu screen is switched from the standby screen, the display direction of the display is switched based on the detection result of the attitude of the playback device, and the display direction is switched from the standby screen to the menu screen. Display on the menu screen in which the display direction is switched based on the detection result of the posture detection means after the standby screen is not switched.
Playback control device. The display on the playback device is a display of display means mounted on the playback device.
The reproduction control apparatus according to claim 1. The switching by the control means is a display direction of an image displayed on the display means,
The display direction is associated with the detection result of the posture detection means.
The reproduction | regeneration control apparatus of Claim 2. The control means controls the display means to display the image displayed on the display means in the associated display direction when the detection results of the posture detection means are the same for a predetermined period;
The reproduction | regeneration control apparatus of Claim 3. The control means performs a process of switching the display direction of the display in response to the start of power supply from the power supply means to the playback device.
The reproduction | regeneration control apparatus as described in any one of Claim 2 to 4. The control means changes from a state in which the standby screen is displayed on the display means to a state in which the data displayed on the display means before the standby screen is displayed is displayed on the display means. A process of switching the display direction of the display according to a change is performed.
The reproduction | regeneration control apparatus as described in any one of Claim 2 to 5. The control means switches functions assigned to the plurality of operation buttons of the operation means based on the detection result of the posture detection means.
The reproduction | regeneration control apparatus in any one of Claims 2-6. The display direction of the display switched by the control means corresponds to a function assigned to a plurality of buttons of the operation means.
The reproduction | regeneration control apparatus of Claim 7. The control means displays a menu screen in the direction of the display screen at the end of the previous time on the display means when the attitude is not detected by the attitude detection means.
The reproduction | regeneration control apparatus as described in any one of Claim 2 to 8. A control method for switching a display direction of display in the playback device based on a detection result of a posture detection unit that is mounted on the playback device and detects the posture of the playback device,
The control method is:
When the restriction function for restricting the operation of the playback device is not released, the standby screen is displayed, the display direction of the standby screen is not switched regardless of the orientation of the playback device, and the restriction function is In response to the release operation, the menu screen is switched from the standby screen, the display direction of the display is switched based on the detection result of the attitude of the playback device, and the display direction is switched from the standby screen to the menu screen. Display on the menu screen in which the display direction is switched based on the detection result of the posture detection means after the standby screen is not switched.
A control method for switching the display direction. The display on the playback device is a display of display means mounted on the playback device.
The control method for switching the display direction according to claim 10. The switching of the display direction is a display direction of an image displayed on the display means,
The control method for switching the display direction according to claim 11, wherein the display direction is associated with a detection result of the posture detection unit. When the detection result by the posture detection means is the same for a predetermined period, the display direction of the displayed image is switched.
The control method which switches the display direction of Claim 11 or 12 . Switching the display direction of the displayed image when the supply of power to the playback device is started from power supply means for supplying power to the playback device;
The control method which switches the display direction as described in any one of Claim 11 to 13. In response to a change from a state in which the standby screen is displayed on the display unit to a state in which an image displayed on the display unit is displayed on the display unit before the standby screen is displayed, the display Change the display direction of the
The control method which switches the display direction as described in any one of Claim 11 to 14. Based on the posture detection result, the function assigned to the plurality of operation buttons of the operation means is switched.
The control method which switches the display direction as described in any one of Claim 11 to 15. The display direction of the display to be switched corresponds to a function assigned to a plurality of buttons of the operation means.
The control method for switching the display direction according to claim 16. When the posture is not detected by the posture detection unit, a menu screen is displayed on the display unit in the direction of the display screen at the previous end.
The control method which switches the display direction as described in any one of Claim 11 to 17.   A recording medium on which a program that causes a computer to execute the process according to claim 10 is recorded. Display means,
Attitude detection means, and
A reproduction apparatus comprising the reproduction control apparatus according to claim 1.

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