Patent Publication Number: US-2009241156-A1

Title: Content reproducing device

Description:
TECHNICAL FIELD 
     The present invention relates to a content reproducing technique, in particular to a content reproducing device that is a type of content reproducing device, such as a portable terminal, obtaining a content through communication. 
     BACKGROUND ART 
     In recent years, the performance of portable terminals has been improving, and services which deliver a content through communication have become active. 
     For example, as described in the following patent documents, a system has been proposed which monitors a communication status and changes a reproducing rate of streaming according to the communication status thus monitored. 
     Patent Document 1: Japanese Patent Application Publication No. 2005-167675 
     Patent Document 2: Japanese Patent Application Publication No. 2004-312569 
     DISCLOSURE OF THE INVENTION 
     Problems to be Solved by the Invention 
     However, even in the case of using the above-techniques, when an interruption actually occurs in the communication status, content reproduction cannot be continued. Especially, when the communication status is not good, it is extremely difficult to continue stream reproduction. 
     An object of the present invention is to enable content reproduction to be continued even when the communication status is not good. 
     Means for Solving the Problems 
     A portable content reproducing device according to the present invention is characterized in that: in the case where the communication status is good, a low bit rate stream file is recorded in a temporary recording device by using a communication band other than a communication band used for high bit rate reproduction; in the case where the communication status is poor or interrupted, a switchover is performed to reproduce a file stored in the temporary storing device from a point at which the communication is interrupted; and, in the case where the communication status is retrieved, high bit rate streaming reproduction is carried out. 
     In the case of performing AV streaming reproduction in a portable content reproducing device, a low bit rate stream file is, while being reproduced, stored in a temporary recording device when the communication status is good, and, when the communication status is bad or interrupted, the following part of the stream is reproduced with the low bit rate stream file having been recorded in the temporary recording device for reproduction. Furthermore, when the communication status is retrieved, a switchover to the original streaming reproduction at a high bit rate is carried out. By having such a configuration, even when the communication status is not good, reproduction can be performed continuously. 
     Here, when download of a low bit rate content is completed, it may be configured that a notification of completion is provided. Furthermore, it may be configured that control is performed in which a content group of multiple kinds of bit rates smaller than the bit rate of the stream content is downloaded by using a surplus band and is recorded in the contents recording part. Selection of a content to be used is accordingly enabled, and convenience regarding content reproduction can be improved. 
     EFFECTS OF THE INVENTION 
     According to the present invention, there is an advantage that, in a portable content reproducing device, even in the case where the communication status is worse than a communication status allowing reception of a streaming content, a content can be reproduced continuously. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a view illustrating a configuration example of a content reproducing system including a portable content reproducing device according to an embodiment of the present invention. 
         FIG. 2  is a functional block view illustrating a configuration example of the portable content reproducing device according to the present embodiment. 
         FIG. 3  is a flowchart diagram illustrating a processing flow at a time of initiating streaming. 
         FIG. 4  is a flowchart diagram illustrating a processing flow during content reproduction. 
         FIG. 5  is a flowchart diagram illustrating a processing flow at a time of completing content reproduction. 
         FIG. 6(A)  is a timing chart diagram regarding content reproduction according to the first embodiment of the present invention, and  FIG. 6(B)  is a diagram regarding a technique according to a modification example of the present embodiment and illustrating an example of a content group existing in a server  1 . 
         FIG. 7(A)  is a timing chart diagram regarding content reproduction according to a first example of the present embodiment, and  FIG. 7(B)  is a diagram regarding the first example and illustrating an example of a content group existing in the server  1 . 
         FIG. 8  is a timing chart diagram regarding content reproduction according to a second example of the present embodiment. 
         FIG. 9  is a timing chart diagram regarding content reproduction according to a third example of the present embodiment. A diagram in  FIG. 10  is also described in association therewith. 
         FIG. 10  is a diagram illustrating a configuration example of a loop file stream according to the third example. 
         FIG. 11  is a view illustrating a configuration example of a buffer memory according to the third embodiment. 
         FIG. 12  is a view illustrating a first display example of a content reproducing device according to the present embodiment. 
         FIG. 13  is a view illustrating a second display example of a content reproducing device according to the present embodiment. 
         FIG. 14  is a view illustrating a third display example of a content reproducing device according to the present embodiment. 
         FIG. 15  is a timing chart diagram regarding content reproduction according to a fourth example of the present embodiment. 
     
    
    
     BEST MODES FOR CARRYING OUT THE INVENTION 
     Hereinafter, a portable content reproducing device according to a first embodiment of the present invention will be described by referring to drawings.  FIG. 1  is a view illustrating a configuration example of a content reproducing system including a portable content reproducing device according to the present embodiment. As shown in  FIG. 1 , the portable content reproducing system according to the present embodiment includes: a server  1  that delivers a content; a network  7 ; a wireless LAN router  5 , for example, that performs routing of a content from the network; and a portable content reproducing device (mobile terminal)  3  that obtains a content from the wireless LAN router  5 . Note that the content reproducing device is not limited to a portable type. 
       FIG. 2  is a functional block view illustrating a configuration example of the portable content reproducing device  3  according to the present embodiment. As shown in  FIG. 2 , the portable content reproducing device  3  according to the present embodiment includes: a CPU  11  that controls the whole device; a memory  15  that functions as a working memory configured to temporarily store a content; an HDD  17  that records a content as well as records a program and the like for content reproduction; an LCD display part  21 ; a user input part  23 ; a wireless LAN communication part  25  that performs communication with the wireless LAN router  5 ; and a communication status detection part  27  that detects a communication status of wireless communication. In some cases, the server  1  may hold contents having the same content at different bit rates. 
       FIG. 3  to  FIG. 5  are a flowchart diagram illustrating a processing flow regarding content reproduction.  FIG. 6  is a timing chart diagram regarding content reproduction.  FIG. 3  is a view illustrating a processing flow at a time of initiating streaming in the portable content reproducing device  3 . As shown in  FIG. 3 , firstly, an instruction to view streaming content is received from a user in a step S 1 , and then the server  1  is directed to initiate streaming reproduction in a step S 2 . In a step S 3 , it is judged whether or not there is a room (surplus band) in a communication bandwidth. If there is no surplus (N), operation skips steps up to a step S 8 , and then proceeds to a processing in  FIG. 5 , which will be described later. In the step S 3 , it is judged whether or not there is a room (surplus band) in the communication band. If there is a surplus (Y), operation proceeds to a step S 4 , and an inquiry whether or not a low bit rate content is available for this content is sent to the server  1 . In a step S 5 , if no low bit rate content is available (N), operation skips steps up to a step S 8 . If a low bit rate content (Y) is available, operation proceeds to a step S 6 , and download of the low bit rate content is initiated by using the surplus band. After the download processing of the low bit rate content is completed in a step S 7 , a user is notified that the download has been completed in the step S 8 . 
       FIG. 4  is a flowchart diagram illustrating a processing during content reproduction. As shown in  FIG. 4 , the communication status is monitored in a step S 11 , and then it is judged in a step S 12  whether or not there is a sufficient remaining band for streaming reproduction. If there is a sufficient band (Y), operation proceeds to a step S 17 , while operation proceeds to a step S 13  if a remaining band is not sufficient (No). In the step S 13 , it is judged whether a content which is currently reproduced is a low bit rate content or streaming. If it is a low bit rate content, operation goes back to the step S 11 . If it is streaming reproduction, operation proceeds to a step S 14 , and a reproduction position A for streaming (for notifying the CPU of a detection result by the communication status detection part  27 ) is obtained in the case where the communication status is retrieved. Next, in a step S 15 , reproduction of a low bit rate content is initiated from the position A. In a step S 16 , a switchover to a low bit rate content reproduction is carried out, and then operation goes back to the step S 11 . If Y in the step S 12 , operation proceeds to a step S 17 . In the step S 17 , it is judged whether a content which is currently reproduced is a low bit rate content or a streaming content. If it is a streaming content, operation goes back to the step S 11 . If it is a low bit rate content, operation proceeds to a step S 18 , and a reproduction position B for low bit rate is obtained. In a step S 19 , reproduction from the reproduction position B is requested to the server  1  ( FIG. 1 ). In a step S 20 , a switchover to streaming reproduction is carried out, and operation goes back to the step S 11 . 
       FIG. 5  is a flowchart diagram illustrating a processing flow at a time of completing. As shown in  FIG. 5 , in a step S 21 , content reproduction (streaming, low bit rate) is completed or a termination instruction from a user is received. Subsequently, a termination processing of reproduction is carried out in a step S 22 , and then, in a step S 23 , it is judged whether or not the low bit rate content needs to be deleted because it is a copyrighted content. If N, the processing is terminated in a step S 25 . If Y, the low bit rate content is deleted in a step S 24 , and then the processing is terminated (step S 25 ). 
     As described above, in a content reproducing technique according to the present embodiment, a portable content reproducing device which obtains a content from a communication part and enables streaming reproduction includes a temporary recording device that is capable of accumulating a content at least temporarily and records a low bit rate stream file in the temporary recording device simultaneously with streaming reproduction. 
     Here, the following relationship, a rate of streaming reproduction&lt;a rate allowing communication, is established. Therefore, by using a surplus band, which is not used for streaming reproduction, within the whole band, a low bit rate stream file having the same content is downloaded to the temporary recording device. A reporting part configured to notify a user, when the download of a low bit rate file is completed, of the completion. 
     In the case where multiple contents having different bit rates are prepared as a low bit rate content provided by the server  1 , information regarding the communication status and a time for how long staying at the location will be and a free space of the hard disk (HDD)  17  are presented to a user. The user can select an appropriate low bit rate content according to bit rate from the provided low bit rate contents. 
     When the communication status is deteriorated or interrupted, there is a possibility that underflow occurs in streaming reproduction at a certain reproducing point. In such a case, a switchover can be performed to reproduce, from the reproducing point, a content file recorded at a low bit rate. 
     The reporting part can notify a user that the communication status has been retrieved during reproduction. In addition, an input part is provided with which a user, who has determined whether or not to switch streaming reproduction, performs input operation in the case where the user actually performs the switchover. 
     When the communication status is retrieved, it is possible to switch, either in response to the input of a user or automatically, to high bit rate streaming reproduction continued from a reproducing point in the reproduction at a low bit rate. A high-quality content can be provided for viewing. 
     Here, after the completion termination of reproduction, in the case where copyright protection of the content is required, it is possible to automatically perform deletion of the low bit rate content stored in the hard disk (HDD). 
     As shown as an example in  FIG. 6(A) , suppose that a maximum capacity band of a system according to the present embodiment is 12 Mbps and streaming reproduction ( 1   a ) is carried out at a time t 1  at 10 Mbps. In such a case, a remaining band is 2 Mbps.  FIG. 6(B)  illustrates three contents held in the server  1 , and indicates that the contents having a bit rate of 10 M, 2 M, and 500 kbps, are available. The communication status is shown as a curbed line in the drawing. 
     Here, the same content is separately downloaded to the HDD at a band of 2 Mbps or smaller (region X: using a content  1   b ). At a time tx, download of the low bit rate content ( 1   b ) is completed. When the streaming reproduction ( 1   a ) at 10 Mbps has proceeded up to 70% (at a time t 2 ), if the communication status is deteriorated, for example, the streaming reproduction ( 1   a ) becomes difficult. Accordingly, reproduction is suspended, for example, at a time t 2 , and then, from the time t 2 , a low bit rate content which has been downloaded separately by the time tx is reproduced as shown by a thick line. In this example, the communication is impossible at a time ty that comes after the time t 2 . However, even in such a case, reproduction can be continued, as shown by the thick line, by using the low bit content which has been downloaded separately. After this, the content  1   b  may remain to be reproduced to its end. However, if the communication status detection part  27  detects that the communication status is retrieved at a time t 3  coming after the time t 2  at which the streaming reproduction ( 1   a ) is interrupted (suppose that 90% of the content has been already reproduced), streaming reproduction of the content can be carried out with a band of 10 Mbps. Then, when viewing of the entire content is completed at a time t 4  (100%), streaming reproduction is ended. 
     As described above, according to the content reproducing technique according to the above embodiment, there is an advantage that, even in the case where the communication status becomes bad, a content can be reproduced continuously by using a low bit rate content that has been recorded. 
     Here, a publicly-known technique can be used to determine from which position of a content the reproduction is started at the switchover of the content. For example, in one employable method, a whole content is assumed to be 100%, and, when the switchover of contents is carried out, the content to be reproduced after the switchover is reproduced from the position determined according to how many percentages (here, suppose X%) of the content has already been reproduced, i.e., from the position after X% from the beginning of the content. 
     Next, another example of the content reproducing technique according to the present embodiment will be described by referring to drawings. The content reproducing technique according to the present embodiment is, as shown in  FIG. 6(B) , characterized in that multiple contents which are each encoded at a different bit rate are downloaded. Suppose, for example, in  FIG. 6(A) , the entire band is 24 Mbps. In this case, when stream reproduction is performed at 10 Mbps, all of the content  1   a  of 10 Mbps, the content  1   b  of 2 Mbps, and the content  1   c  of 500 kbps, which are show in  FIG. 6(B) , can be downloaded. Thereafter, when the communication status is deteriorated, according to a user designation, it can be determined which one of the contents  1   a  to  1   c  is to be reproduced. For example, according to a remaining battery level in the content reproducing device, it can be determined which one of the contents  1   a  to  1   c  is to be reproduced. Furthermore, on a temporal axis, reproduction can be performed while selecting contents having different bit rates. 
     Next, a first example of the present embodiment will be described by referring to drawings.  FIG. 7(A)  is a timing chart diagram regarding content reproduction according to the present example, and  FIG. 7(B)  is a diagram illustrating an example of a content group existing in the server  1  regarding the first example. 
     As for the example illustrated in  FIG. 7 , the diagram illustrates an example in which the streaming reproduction ( 1   a ) is initiated at a time t 1  and download of a low bit rate content is continuously carried out even at a time t 2  at which the streaming reproduction ( 1   a ) is interrupted because the communication band is narrowed. In this case, a download processing of the low bit rate content is continuously carried out just before a timing ty at which the communication is interrupted. At t 4 , content reproduction is finished. 
     Here, from t 1  to t 2  and from t 3  to t 4 , streaming reproduction at a high bit rate is carried out. 
     With such a configuration, as shown in  FIG. 7(A) , even in the case where an available communication band is only one which does not allow streaming reproduction at a high bit rate, the period of the reproduction can be made longer by performing a download processing of a low bit rate content. Therefore, the communication band can be efficiently used. 
     Next, a content reproducing technique according to a second example of the present embodiment will be described by referring to drawings. As shown in  FIG. 8 , the communication status is monitored from a timing t 1  at which the streaming reproduction ( 1   a ) is initiated. Then, if, at a time point, for example, t L1 , which comes before a timing t 2  at which streaming reproduction is interrupted, a decrease in the communication band is detected as shown by a symbol L 1 , it can be predicted that streaming reproduction will be impossible at a certain timing coming thereafter. Therefore, before the timing t 2  at which streaming reproduction is interrupted, reproduction of a download content can be prepared. Then, at the interruption timing t 2 , reproduction at a low bit rate can be immediately carried out. In the meantime, as for a region AR 1  coming after t 2 , streaming is resumed at t 3 , a low bit rate content ( 1   b ) is downloaded at tx, and reproduction is finished at t 4 . In this case, regarding the period from t 2  to t 3 , although streaming reproduction at a high bit rate cannot be performed, it can be used for download of a low bit rate content. Accordingly, the communication band can be used efficiently. Furthermore, judgment regarding a switchover between streaming reproduction and reproduction of a low bit rate content can be performed earlier, a processing rate and processing efficiency can be further improved. 
     In the case where the reception status of communication starts to be deteriorated as described above, if a low bit rate content has not been acquired up to a position allowing reproduction thereof, streaming currently being reproduced is continuously carried on while performing congestion control or the like. If a low bit rate content has been acquired up to a position allowing reproduction thereof, a content to be reproduced is switched to a low bit rate content. Then, if ally part of the low bit rate content has not been acquired, it is possible to perform control so as to give priority to download of the remaining low bit content by using the communication band. 
       FIG. 9  is a Liming chart diagram regarding content reproduction according to a third example of the present embodiment.  FIG. 9(A)  is a diagram illustrating an example of a content which is held in a server  1   x  and can be provided to the content reproducing device. As shown in the drawing, in a server apparatus  1   x , there are a content  1   x - 1  of a high bit rate (10 M) and a content  1   x - 2  of a low bit rate (500 kb) which can send a content of, for example, n (minutes) after the content  1   x - 1  to the content reproducing device. The server apparatus  1   x  sends both contents simultaneously to the content reproducing device. A view illustrating this operation is  FIG. 9(B) . Real-time streaming viewing is initiated at Ta, and, at the same time, acquisition of a content, which is being sent at a low bit rate, for a time point Ta+n minutes is initiated. Here, in a region AR 2 , a low bit rate content for the reproduction after n minutes is always streamed. Accordingly, Ta+n minutes thereafter, a switchover to a low bit rate content is possible. A content at the AR 2  part can be subjected to download of a low bit rate content in a AR 3  region which is initiated at Tb as shown by a symbol L 2 . Here, since the communication status is deteriorated at Tb, both reproduction of a low bit rate content and all possible download processing (AR 3 ) of a low bit rate content can be performed. Note that, even if the communication is completely interrupted at Tc, reproduction of a low bit rate content is possible for n minutes from this point. If the communication starts is retrieved a little before a time Td, acquisition by download of a low bit rate content can also be resumed (a region indicated by a symbol AR 4 ). Furthermore, when the communication status is retrieved, a switchover to real-time streaming at a time Te is possible. In addition, as shown by a symbol AR 5 , acquisition of a low bit rate content is possible. Here, at the time Tc, a low bit content up to Tc+n minutes has been obtained in AR 3 . Therefore, if Tc+n&lt;Te, viewing of the whole content without interruption is possible. Since acquisition of a low bit rate content from the time Td to a time point Td+n minutes has been initiated, it can be judged that, Td+n minutes thereafter, a switchover to a low bit rate content is possible. 
       FIG. 10  is a diagram illustrating a configuration example of a loop file stream according to the third example regarding a content after n minutes. Here, the loop files illustrated in  FIG. 10(A)  to  FIG. 10(C)  are also arranged on a time axis in  FIG. 9 . Tcurrents (a to c) in  FIG. 10  each represent a time point indicated by an arrow in  FIG. 9 , and Tcurrent (a) represents the time at a certain time point between Ta and Ta+n minutes, Tcurrent (b) represents the time at a certain time point between Ta+n and Tc, and Tcurrent (c) represents the time at a certain time point between Tc and Td. 
     As shown in  FIG. 10 , a concept of a loop stream file having a size of a bit rate×time will be described. When writing is reaching the end of a loop file  31   a,  operation goes back again to a starting position P 3  and writing is initiated therefrom. Continuous writing with a constant file size is possible. “Reading position” and “writing position” in  FIG. 10  respectively indicate their positions at Tcurrent, and the description of “content data at a time point of . . . ” means that the content of the data is a viewable content at the time point. Therefore, in the case where the current time is Tcurrent, at the time of Tcurrent, a content at a time point “Tcurrent+n minutes” has been acquired as a low bit rate content. 
       FIG. 10(A)  is a diagram illustrating a progression of writing of a low bit rate stream started from the starting position of the file (described in association with  FIG. 9 ). To be more specific, recording of content data for a time point “Ta+n minutes” is initiated from a time Ta, and writing of content data for a time point “Tcurrent (a)+n minutes” is in progress at Tcurrent (a). Content data is further recorded continuously, and then a time “Ta+n minutes” has come. In the drawing, the halfway progression thereof is illustrated. In the case where a current time during this period is set to Tcurrent (a), firstly, recording of a content for the time point “Ta+n minutes” is initiated from the time Tcurrent (a) (=Ta), and a switchover to a low bit rate content is not possible until Tcurrent (a) reaches Ta+n. A writing position at the time Tcurrent (a) corresponds to the content data at a time point “Tcurrent+n minutes.” Here,  FIG. 10(B)  illustrates a status of a loop stream file from Ta+n minutes to Tc in  FIG. 9 , and, during this period, a switchover to a low bit content is possible. In other words, at a writing position at a time Tcurrent (b) in  FIG. 9(B) , content data at a time point “Tcurrent (b)+n minutes” has been recorded. A reading position at the time Tcurrent (b) is content data for the time point Tcurrent (b). 
     Next, as shown in  FIG. 10(C) , in a loop stream file  31   c  including a period of interrupted communication, after a switchover to a low bit rate content, writing does not proceed when the communication is being interrupted. After the communication is recovered, a wiring position proceeds. However, in such a case, some period of time is missing. Accordingly, n minutes after the position, the status in which a switchover to a low bit rate content is possible is achieved. A reading position at a time Tcurrent (c) is content data at the time point Tcurrent (c). For ease in understanding, the loop stream file in  FIG. 10  is also described in  FIG. 9  in association therewith. In the meantime, as shown in  FIG. 11 , regarding a status in which a part corresponding to the loop stream file  31  (for n minutes) proceeds on the time axis, there is also a method in which a buffer memory is used to sequentially erase a region AR 11  before the loop stream file  31 . 
       FIG. 15  is a diagram corresponding to  FIG. 9 . As similar to  FIG. 9 ,  FIG. 15  shows a case where a high bit rate content is continuously streamed like a broadcast, and where a low bit rate content is downloadable not as a streaming but as a content. 
       FIG. 15(B)  is a timing chart diagram regarding content reproduction according to a fourth example of the present embodiment. A real-time streaming viewing is initiated at Ta, and, at the same time, download at a low bit rate by using a surplus band indicated by AR 1  is continuously carried out until a portion having the size of a loop stream file (n minutes) has been recorded. In other words, the region of AR 1  is used for download of an n-minute loop stream. At a time Tb′, after the n-minute content has been accumulated in the loop stream file, a switchover is performed so as to download a low bit rate content corresponding to a portion of a time proceeded, and recording is continued by using the communication region of AR 2 . At a time Tb, if the communication status is so deteriorated that reproduction of a high bit rate streaming content cannot be continued, reproduction is switched to that at a low bit rate. During the period from Tb to Tc, download of the low bit rate content can be also carried out as much as possible. Even if the communication is completely interrupted at Tc, reproduction of the low bit rate content is possible for n minutes. If the communication starts to be recovered just before a time Td, acquisition of the low bit rate content by download can also be resumed. At this time, the amount of content recorded in the loop stream file is reduced by a portion of time of the communication interruption. Therefore, as similarly to AR 1 , until an n-minute low bit rate content has been accumulated in the loop stream file, download of the low bit rate content is continued (a region indicated by a symbol AR 4 ). 
     When the communication status is further retrieved at Te, a switchover to the high bit rate streaming content can be carried out. During the time from Te to Tf, by using a surplus band, download of the low bit rate content can be continued. At a time Tf, when an n-minute low bit rate content has been accumulated in the loop stream file, a switchover is performed so as to download the low bit rate content by a portion of a time proceeded. 
       FIG. 15(   c ) is a time chart illustrating the amount of the low bit rate content accumulated in the loop stream file. During the period from Ta to Tb′, the low bit rate content is downloaded by using the entire surplus band until the low bit rate content for n minutes is accumulated in the loop stream file. Accordingly, the writing rate is faster than the reading rate, and the amount of the content accumulated in the loop stream file keeps increasing. During the period from Tb′ to Tc, the writing rate and the reading rate of the loop stream file are kept the same. Accordingly, the amount of the content accumulated in the loop stream file is hardly changed. When download of the low bit rate content becomes impossible at Tc, writing is terminated while only reading proceeds. Accordingly, the amount of the low bit rate content accumulated in the loop stream file starts to be decreased. When the communication is recovered at Td, the low bit rate content may be continuously downloaded by using the communication region, for example, the entire communication region since the low bit rate content for n minutes has not been accumulated. Then, even after the communication is further recovered and a switchover to high bit rate streaming is performed at Te, the low bit rate content may be continuously downloaded by using a surplus band until the low bit rate content for n minutes is accumulated. When the low bit rate for n minutes is already accumulated in the loop stream file at Tf, the download rate is set to be equal to the reading rate. Therefore, the amount of the content accumulated in the loop stream file does not change any more. 
     Here, in  FIG. 15(C) , from Ta to Tb′ and from Td to Te, for simplification of the drawing, the status in which the amount of the content increases and decreases is shown in a linear manner. However, in actuality, the amount fluctuates by the communication status and the like, thereby drawing a curve. Here, it is illustrated as a schematic drawing. 
     Next, a display example in the content reproducing device will be described.  FIG. 12  is a view illustrating a first display example of the content reproducing device of according to the present embodiment. A display screen  21  of the content reproducing device illustrated in  FIG. 12  may be provided, for example, at the right bottom corner thereof, with a progress status display region  21   a  of download processing of a low bit rate content. An enlarged view of the progress status display region  21   a  illustrated on the right hand side provides the display of a memory unit having an HDD shape in which a part  22   a  indicating an already-downloaded portion and a part  22   b  indicating a still-empty portion are displayed in a visually distinguishable manner. Here, they are distinguished by color. By looking at this display, it is possible to know the progress status regarding the download of the low bit rate content. Furthermore, the progress status display region  21   a  may be configured to, for example, change color when reproduction of a low bit content becomes possible, and to change color to indicate that a low bit rate content is being reproduced. 
       FIG. 13  is a view illustrating a second display example of the content reproducing device according to the present embodiment. As shown in  FIG. 13 , for example, it is also possible to display a communication band status display region  21   b  indicating current communication band information near the progress status display region  21   a.  The communication band status display region  21   b  is composed of a bar-chart display having bars  21   d - 1  to  21   b - 5  with different heights, and is configured to display whether or not streaming reproduction is possible with a certain threshold value as a reference. If it is set that streaming reproduction is possible when up to  21   b - 3  are colored, a user can distinguish at a glance whether or not streaming reproduction is possible by looking at the display. Furthermore, it is also possible to allow a user to understand this more easily by changing color during streaming reproduction. 
     Next, by referring to  FIG. 14 , a third display example of the content reproducing device according to the present embodiment will be described. As shown in  FIG. 14 , in the content display part  21 , an announce display part  21   c  is provided, and is configured to announce various information. For example, when the communication status is deteriorated, a display  21   c - 1  announces “a content will be switched,” a display  21   c - 2  announces “the communication has been interrupted,” a display  21   c - 3  announces “the communication status has been retrieved, and a switchover to streaming will be performed,”  21   c - 4  announces “low bit rate content reproduction in progress,” and  21   c - 5  announces “streaming reproduction in progress.” There is an advantage that a user can understand the current status correctly by receiving such announces. 
     As describe above, there is an advantage that using the content reproducing technique according to the present embodiment further enhances flexibility in content reproduction because contents having different bit rates are downloaded to a HDD in a content reproducing device. 
     INDUSTRIAL APPLICABILITY 
     The present invention can be used for a content reproducing device, for example, a portable terminal and the like, that allows streaming reproduction.