JP2006211128A - Image processing system and image processing control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image processing system for applying compression coding to consecutive shot image data and transferring the resulting data to a recording medium, the image processing system in which high speed consecutive shots are realized without being restricted by a capacity of a coding buffer. <P>SOLUTION: When an image processing apparatus 100 controls the coding buffer 104 as a ring buffer, applies compression coding to the image data, stores the coded data into the coding buffer 104, and thereafter transfers the resulting data to the recording medium 130 via a host CPU 120 for carrying out major control of the system, the host CPU 120 informs the image processing apparatus 100 of reading completion of the coded data, and when receiving a coding processing start instruction or the notice of read completion of the coded data from the host CPU 120, the image processing apparatus 100 informs the host CPU 120 about the number of coding completion frames, and the host CPU 120 reads the coded data by the number of coding completion frames from the coding buffer 104. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an image processing control technique that enables high-speed continuous shooting in an image processing system capable of continuous shooting.

  In a conventional image processing system capable of continuous shooting, when JPEG compression encoding processing is performed on an image signal obtained by continuously shooting a subject with a shooting means such as a camera, software installed in a microcomputer that controls the system or Since it is difficult to increase the speed when encoding is performed by hardware, a microcomputer that uses an inexpensive low-speed microcomputer is used, and apart from this, it is common to perform JPEG compression encoding using an image processing dedicated LSI. ing.

  In an image processing system such as a digital camera, a memory card using an electrically erasable non-volatile memory such as a flash memory is used as a recording medium. Even if JPEG compression encoding is speeded up using a processing-dedicated LSI, writing time to a memory card and processing time of a low-speed microcomputer have become a bottleneck to speeding up continuous shooting.

  Conventionally, as a countermeasure against this problem, instead of transferring compressed encoded data by the image processing dedicated LSI to the memory card for each frame, the compressed encoded data is stored in the encoding buffer in the order of continuous shooting, and continuous shooting is completed. At that time, Patent Document 1 discloses a technique for transferring a plurality of frames of compressed encoded data stored in an encoding buffer by continuous reading to a memory card.

In addition, since the compression rate by JPEG compression encoding varies greatly depending on the type of image data, the compression encoded data may not fit in the encoding buffer depending on the image data. At that time, Patent Document 1 discloses a method of transferring the compressed encoded data remaining in the encoding buffer to the memory card and changing the setting of the encoding buffer to continue shooting.
JP 2000-125254 A

  In an image processing system that transfers conventional compression-encoded data to a memory card for each frame, writing time to the memory card becomes a bottleneck and high-speed continuous shooting is difficult. Further, in the transfer method after completion of continuous shooting as shown in Patent Document 1, only continuous shooting within the capacity of the encoding buffer can be realized, and when compressed encoded data does not fit in the encoding buffer, Even if the shooting was continued after changing the setting of the encoding buffer, there was a problem that an image frame dropped.

  According to the present invention, in an image processing system in which continuously shot image data is compressed and encoded, stored in an encoding buffer, and then transferred to a medium such as a memory card, the capacity of the encoding buffer is not limited, and image frame dropping occurs. An object of the present invention is to provide an image processing system and an image processing control method that enable high-speed continuous shooting.

  The image processing system of the present invention is an image processing system in which image data continuously shot is compressed and encoded by an image processing unit, stored in an encoding buffer, and then transferred to a recording medium via a host CPU that performs main control of the system. Means for controlling the encoding buffer as a ring buffer, means for notifying the image processing unit from the host CPU that the encoded data has been read, and the image processing unit encoding processing from the host CPU. And a means for notifying the host CPU of the number of frames that have been encoded when the start instruction or the notification of completion of reading of the encoded data is received.

  According to the above configuration, the encoding buffer can be controlled as a ring buffer, and the host CPU reads out the encoded data of the notified number of encoding completion frames, and sends it to the image processing unit every time the reading is completed. The image processing unit can repeat the cycle of notifying the host CPU of the number of frames that have been encoded in the encoded data stored in the encoding buffer. Encoded data can be stored, and encoded data of a plurality of frames accumulated in the encoding buffer is transferred to the host CPU with the highest efficiency, thereby enabling high-speed continuous shooting without interrupting continuous shooting.

  The image processing control method of the present invention is an image processing method in which continuously shot image data is compressed and encoded by an image processing unit and stored in an encoding buffer, and then transferred to a recording medium via a host CPU that performs main control of the system. When the host CPU is notified of the completion of reading of encoded data to the image processing unit, and the image processing unit is received an instruction to start encoding processing or a notification of completion of reading of the encoded data from the host CPU. The host CPU is notified of the number of frames that have been encoded, and the host CPU is caused to read out the encoded data of the number of frames that have been encoded from an encoding buffer that is controlled as a ring buffer.

  According to the above configuration, the encoding buffer is controlled as a ring buffer, the host CPU reads out the encoded data of the notified number of encoding completion frames, and notifies the image processing unit every time the reading is completed, Since the image processing unit repeats a cycle of notifying the host CPU of the number of frames of encoding data stored in the encoding buffer, the encoded data can be stored without being limited by the capacity of the encoding buffer, The encoded data of a plurality of frames stored in the encoding buffer is transferred to the host CPU with the highest efficiency, and has the effect of enabling high-speed continuous shooting without interrupting continuous shooting.

  In addition, by having a sequence in which the host CPU notifies the image processing unit of the completion of reading of the encoded data, and the image processing unit notifies the host CPU of the number of encoded frames, the encoding buffer capacity and the image processing Adjustment of the encoding processing performance by the CPU and the processing performance of the host CPU can be performed automatically, and continuous shooting performance corresponding to the adjustment can be obtained. It has a possible effect.

  According to the present invention, encoded data can be stored without being limited by the capacity of the encoding buffer, and encoded data of a plurality of frames accumulated in the encoding buffer is transferred to the host CPU most efficiently, and continuous shooting is interrupted. High-speed continuous shooting is possible without doing so.

  FIG. 1 is a block diagram showing a configuration of an image processing system according to an embodiment of the present invention. In FIG. 1, 100 is an image processing apparatus, 110 is a camera, 120 is a host CPU, and 130 is a storage medium. Further, in the image processing apparatus 100, 101 is a CPU, 102 is an image buffer, 103 is a JPEG engine, 104 is an encoding buffer, and 121 is a memory in the host CPU 120.

  The configuration of FIG. 1 shows an operation in which the image processing apparatus 100 encodes an image signal from the camera 110, transfers the encoded data to the host CPU 120, and saves it in the storage medium 130.

  The image processing apparatus 100 buffers the image signal from the camera 110 in the image buffer 102, controls the JPEG engine 103 by the CPU 101, encodes the image data in the image buffer 102, and stores it in the encoding buffer 104.

  The host CPU 120 extracts the encoded data stored in the encoding buffer 104 at an arbitrary timing and stores it in the memory 121. The host CPU 120 performs control to save the encoded data saved in the memory 121 in the storage medium 130 or in the memory 121.

  FIG. 2 is a diagram for explaining how the encoded data is transferred between the image processing apparatus 100 and the host CPU 120. Here, a state of the encoded data transfer in the case of performing six consecutive shots is shown.

  The encoded data encoded by the image processing apparatus 100 is temporarily stored in the encoding buffer 104. Here, it is assumed that encoded data for six consecutive shots can be stored in the encoding buffer 104. At this time, the image processing apparatus 100 continuously performs encoding, and encoded data is transferred from the host CPU 120 at an arbitrary timing.

  As the number of frames of encoded data to be transferred at that time, one encoded data 1 is transferred, two encoded data 2 and 3 are transferred, and three encoded data 4, 5 and 6 are transferred and transferred. Encode at high speed while improving efficiency.

  FIG. 3 shows a control sequence of encoded data transfer between the image processing apparatus 100 and the host CPU 120 in this case. FIG. 4 is a flowchart for explaining this control sequence. Hereinafter, the operation in this case will be described in detail with reference to FIG. Here, the steps of the flowchart are indicated by (xxx).

(400) A JPEG encoding start instruction is received from the host CPU.
(401) The image signal 1 is read from the camera and encoded by the JPEG engine.
(402) An encoding completion notification is transmitted to the host CPU (completed number of sheets: 1).
(403) The image signal 2 is read from the camera and encoded by the JPEG engine.
(404) The image signal 3 is read from the camera and encoded by the JPEG engine.
(405) The host CPU reads the encoded data 1.
(406) An encoded data read completion instruction is received from the host CPU (number of read completed sheets: 1).
(407) An encoding completion notification is transmitted to the host CPU (number of completed sheets: 2).
(408) The image signal 4 is read from the camera and encoded by the JPEG engine.
(409) The image signal 5 is read from the camera and encoded by the JPEG engine.
(410) The image signal 6 is read from the camera and encoded by the JPEG engine.
(411) The host CPU reads the encoded data 2 and 3.
(412) An encoded data read completion instruction is received from the host CPU (number of read completed sheets: 2).
(413) An encoding completion notification is transmitted to the host CPU (completed number of sheets: 3).
(414) The host CPU reads the encoded data 4, 5, and 6.
(415) An encoded data read completion instruction is received from the host CPU (read completed number of sheets: 3).
(416) A JPEG encoding completion report is transmitted to the host CPU.

  In this way, when the image processing apparatus 100 receives an encoded data read completion instruction from the host CPU 120, the image processing apparatus 100 notifies the host CPU 120 of the number of encoding completions. The transfer efficiency can be improved while reducing the number of conversion completion notifications and performing high-speed encoding without interrupting continuous shooting control.

  The above explanation is for the case where encoded data for continuous shooting can be stored in the encoding buffer 104. Next, the operation when the encoded data for continuous shooting exceeds the capacity of the encoding buffer 104 will be described. .

  FIG. 5 is a diagram for explaining a state in which encoded data is transferred between the image processing apparatus 100 and the host CPU 120 when encoded data for six consecutive shots cannot be stored in the encoding buffer 104 when performing six continuous shooting. . Here, the encoding buffer 104 has a ring buffer configuration.

  The encoded data encoded by the image processing apparatus 100 is temporarily stored in the encoding buffer 104. At this time, the image processing apparatus 100 continuously performs encoding, and encoded data is transferred from the host CPU 120 at an arbitrary timing.

  As the number of frames of encoded data to be transferred at that time, one encoded data 1 is transferred, two encoded data 2 and 3 are transferred, and three encoded data 4, 5 and 6 are transferred and transferred. Encode at high speed while improving efficiency. At this time, due to the ring buffer configuration of the encoding buffer 104, the encoded data 6 is stored after the encoded data 1 is transferred.

  FIG. 6 shows a control sequence of encoded data transfer between the image processing apparatus 100 and the host CPU 120 in this case. FIG. 7 is a flowchart for explaining this control sequence. Hereinafter, the operation in this case will be described in detail with reference to FIG.

(700) A JPEG encoding start instruction is received from the host CPU.
(701) The image signal 1 is read from the camera and encoded by the JPEG engine.
(702) An encoding completion notification is transmitted to the host CPU (completed number of sheets: 1).
(703) The image signal 2 is read from the camera and encoded by the JPEG engine.
(704) The image signal 3 is read from the camera and encoded by the JPEG engine.
(705) The host CPU reads the encoded data 1.
(706) An encoded data reading completion instruction is received from the host CPU (reading completion number: 1).
(707) An encoding completion notice is transmitted to the host CPU (completed number: 2).
(708) The image signal 4 is read from the camera and encoded by the JPEG engine.
(709) The image signal 5 is read from the camera and encoded by the JPEG engine.
(710) It is determined that the encoded data 6 cannot be stored at the end of the encoding buffer.
(711) The image signal 6 is read from the camera, encoded by the JPEG engine, and the encoded data 6 is stored at the head of the encoding buffer.
(712) The host CPU reads the encoded data 2 and 3.
(713) An encoded data reading completion instruction is received from the host CPU (reading completion number: 2).
(714) An encoding completion notification is transmitted to the host CPU (number of completed sheets: 3).
(715) The host CPU reads the encoded data 4, 5, and 6.
(716) An encoded data read completion instruction is received from the host CPU (number of read completed sheets: 3).
(717) A JPEG encoding completion report is transmitted to the host CPU.

  In this way, the image processing apparatus 100 instructs the host CPU 120 to read out the encoded data, and the encoding buffer 104 is ringed together with the function of notifying the host CPU 120 of the number of encoding completions from the image processing apparatus 100. By adopting a buffer configuration, the speed of continuous shooting can be increased without interrupting continuous shooting control without being limited by the capacity of the encoding buffer.

  The image processing system and the image processing control method of the present invention can store encoded data without being limited by the capacity of the encoding buffer, and the encoded data of a plurality of frames accumulated in the encoding buffer is most efficiently transmitted to the host CPU. Useful as an image processing control technology that enables high-speed continuous shooting in an image processing system that is capable of high-speed continuous shooting without interrupting continuous shooting. It is.

1 is a block diagram showing a configuration of an image processing system according to an embodiment of the present invention. The figure explaining the mode of the encoding data transfer between an image processing apparatus and host CPU. FIG. 6 is a control sequence diagram of encoded data transfer between the image processing apparatus and a host CPU. 6 is a flowchart for explaining a control sequence of encoded data transfer between an image processing apparatus and a host CPU. The figure explaining the mode of the encoding data transfer between an image processing apparatus and host CPU. FIG. 6 is a control sequence diagram of encoded data transfer between the image processing apparatus and a host CPU. 6 is a flowchart for explaining a control sequence of encoded data transfer between an image processing apparatus and a host CPU.

Explanation of symbols

100 Image processing apparatus 101 CPU
102 Image buffer 103 JPEG engine 104 Encoding buffer 110 Camera 120 Host CPU
121 memory 130 storage medium 400-416, 700-717 processing steps

Claims (5)

An image processing system in which continuously captured image data is compressed and encoded by an image processing unit and stored in an encoding buffer, and then transferred to a recording medium via a host CPU that performs main control of the system.
Means for controlling the encoding buffer as a ring buffer;
Means for notifying completion of reading of encoded data from the host CPU to the image processing unit;
Means for notifying the host CPU of the number of encoded frames from the image processing unit when the image processing unit receives an instruction to start encoding processing or a notification of completion of reading of the encoded data from the host CPU; ,
An image processing system comprising: In an image processing control method in which continuously captured image data is compressed and encoded by an image processing unit and stored in an encoding buffer, and then transferred to a recording medium via a host CPU that performs main control of the system.
When the host CPU is notified of the completion of reading of the encoded data to the image processing unit, and when the image processing unit receives an encoding process start instruction or a notification of completion of reading of the encoded data from the host CPU An image processing control method for causing the host CPU to notify the number of encoded frames, and causing the host CPU to read out the encoded data for the number of encoded frames from an encoding buffer controlled as a ring buffer.   A program for controlling the image processing unit constituting the image processing system according to claim 1, wherein the computer receives an encoding process start instruction or a read completion notification of the encoded data from the host CPU. A program that functions as means for notifying the host CPU of the number of frames that have been encoded.   2. A program for controlling the host CPU constituting the image processing system according to claim 1, wherein the computer functions as means for notifying the image processing unit of completion of reading of encoded data.   A recording medium storing the program according to claim 3.

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