TW201611563A - Enveloping for device independence - Google Patents

Enveloping for device independence Download PDF

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Publication number
TW201611563A
TW201611563A TW104126480A TW104126480A TW201611563A TW 201611563 A TW201611563 A TW 201611563A TW 104126480 A TW104126480 A TW 104126480A TW 104126480 A TW104126480 A TW 104126480A TW 201611563 A TW201611563 A TW 201611563A
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digital
data
cloud
wavefront
file
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TW104126480A
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Chinese (zh)
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成棟 章
李卓諭
杰弗裡 章
史蒂夫 陳
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空間數碼系統公司
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Priority claimed from US14/685,665 external-priority patent/US10264052B2/en
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Publication of TW201611563A publication Critical patent/TW201611563A/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N21/00Selective content distribution, e.g. interactive television or video on demand [VOD]
    • H04N21/20Servers specifically adapted for the distribution of content, e.g. VOD servers; Operations thereof
    • H04N21/23Processing of content or additional data; Elementary server operations; Server middleware
    • H04N21/234Processing of video elementary streams, e.g. splicing of video streams or manipulating encoded video stream scene graphs
    • H04N21/2347Processing of video elementary streams, e.g. splicing of video streams or manipulating encoded video stream scene graphs involving video stream encryption
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L67/00Network arrangements or protocols for supporting network services or applications
    • H04L67/01Protocols
    • H04L67/10Protocols in which an application is distributed across nodes in the network
    • H04L67/1097Protocols in which an application is distributed across nodes in the network for distributed storage of data in networks, e.g. transport arrangements for network file system [NFS], storage area networks [SAN] or network attached storage [NAS]
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N21/00Selective content distribution, e.g. interactive television or video on demand [VOD]
    • H04N21/20Servers specifically adapted for the distribution of content, e.g. VOD servers; Operations thereof
    • H04N21/23Processing of content or additional data; Elementary server operations; Server middleware
    • H04N21/235Processing of additional data, e.g. scrambling of additional data or processing content descriptors
    • H04N21/2351Processing of additional data, e.g. scrambling of additional data or processing content descriptors involving encryption of additional data
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N21/00Selective content distribution, e.g. interactive television or video on demand [VOD]
    • H04N21/20Servers specifically adapted for the distribution of content, e.g. VOD servers; Operations thereof
    • H04N21/23Processing of content or additional data; Elementary server operations; Server middleware
    • H04N21/238Interfacing the downstream path of the transmission network, e.g. adapting the transmission rate of a video stream to network bandwidth; Processing of multiplex streams
    • H04N21/2389Multiplex stream processing, e.g. multiplex stream encrypting
    • H04N21/23895Multiplex stream processing, e.g. multiplex stream encrypting involving multiplex stream encryption

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  • Engineering & Computer Science (AREA)
  • Signal Processing (AREA)
  • Multimedia (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Theoretical Computer Science (AREA)
  • Image Processing (AREA)
  • Information Transfer Between Computers (AREA)

Abstract

Cloud computing enables a user to access all his or her applications and documents from anywhere in the world, freeing the user from the confines of the desktop. This invention comprises techniques on how to enhance privacy via enveloping/de-enveloping for device independence in cloud computing. Embedded data by the enveloping techniques may be digital voices, image, video, or other digital data. We use 4-to-4 WF muxing to exemplify the implementations, introducing customized enveloping/de-enveloping with other known digital files or parameters.

Description

有設備獨立性的數碼加封Digital seal with device independence

本發明涉及雲儲存和傳輸的數據包裝(數碼加封)的方法及其架構。此數碼加封的方法和架構是利用波前覆用(WF覆用)。它的重點是數碼加封及數碼解加封之外觀及加封后數據的可靠性。The present invention relates to a method of data packaging (digital encapsulation) for cloud storage and transmission and an architecture thereof. The method and architecture of this digital seal is to use wavefront override (WF override). Its focus is on the appearance of digital seals and digital unsealing and the reliability of data after sealing.

根据mailonline(http://www.dailymail.co.uk)於2014年8月31日 的報導,備受矚目的演員,模特,歌手,和主持人的裸體照片已經貼在網上。顯然是出自於黑客洩漏與蘋果的iCloud服務之洩露的結果。這些出現下4chan 上的照片(4chan是一家圖像分享論壇)是由其某一用戶上傳的101名人照片;包括珍尼佛‧勞倫斯,阿麗亞娜  格南地,維多利亞‧加斯提斯,與凱特  厄普頓的私人照片。這些照片是在周日晚上張貼的。據說是因iCloud中的漏洞讓名人的手機被黑客入侵。蘋果公司拒絕對此發表評論。名人的隱私被嚴重的侵害了。According to a report by mailonline (http://www.dailymail.co.uk) on August 31, 2014, nude photos of highly regarded actors, models, singers, and presenters have been posted online. Apparently it was the result of a hacker leak and the leak of Apple's iCloud service. These photos appear on 4chan (4chan is an image sharing forum) is a 101-person photo uploaded by one of its users; including Jennifer Lawrence, Ariane Glamand, Victoria Gastis, Private photo with Kate Upton. These photos were posted on Sunday night. It is said that the celebrity's mobile phone was hacked because of a vulnerability in iCloud. Apple declined to comment. The privacy of celebrities has been seriously violated.

在雲計算和雲存儲的更好隱私保護是確切需要的。數碼加封技術將會加強雲計算和雲存儲的隱私保護。Better privacy protection in cloud computing and cloud storage is exactly what is needed. Digital packaging technology will enhance the privacy protection of cloud computing and cloud storage.

波前覆用技術已經用在上面提到的美國專利申請書中的應用(PA號12/848953,13/938268,13/953715)。與道統的雲計算和存儲技術相比,波前覆用技術可使用較少的內存空間,以達到更好的冗餘,更高之的可靠性和存活力。此外,這些技術也可使用於監測存儲數據的完整性,而無需審閱所存儲數據的本身。相同的技術可擴展到雲上的數據流;包括雲視頻流及雲音頻流。Wavefront overlying techniques have been used in the above mentioned U.S. patent application (Pa. No. 12/848,953, 13/938,268, 13/953,715). Compared to the cloud computing and storage technologies of the system, the wavefront overlay technology can use less memory space for better redundancy, higher reliability and survivability. In addition, these techniques can also be used to monitor the integrity of stored data without having to review the stored data itself. The same technology can be extended to data streams on the cloud; including cloud video streams and cloud audio streams.

另有兩項更需關注的議題。其一是有關運營商提供安全和加密存儲服務。然而,檔案隱私是靠在運營商伺服器端的檔案加密。許多運營商的操作員仍可夠得到加密程式。 所以客戶的檔案隱私必須倚賴運營商及伺服器操作員的頭班操守和誠信度。其二是關於雲儲存數據的殘留權利的關注; 這項議題目前仍在熱烈的爭論中。There are two other issues that require more attention. One is related to the provision of secure and encrypted storage services by operators. However, file privacy is based on file encryption on the server side of the carrier. Many operators' operators still have access to encryption programs. Therefore, the customer's file privacy must rely on the operator's and server operators' first-hand ethics and integrity. The second is the concern about the residual rights of cloud storage data; this issue is still under intense debate.

許多波前覆用發明申請書的專利權利要求意圖解決這些議題;增強數據雲傳輸和數據雲儲存的的私密性和可靠性。許多在雲端的數據甚至可以是圖像或音頻有關的。由於多組雲運輸或儲存的數據會在客戶端做預處理,每組雲傳輸或雲儲存的數據是一組已經經過波前覆用轉換處理過的數據。 這些覆用處理過的數據已不是能解讀的原數據本身。所以申請書中所建議的數碼加封法應會讓客戶對這些雲儲存數據的私密性和可靠性更有信心,而這些信心不再只倚賴對經營者的頭班操守和誠信度的關注。在數碼加封法中, 已知的圖像,音頻,或多媒體數據全都可以用作數碼信封來做為推展私密可靠的雲數據存儲和運輸之手段。大多數的商機都瞄準在遊戲和娛樂雲通信應用。它可用在各種數字商品版權管理和複製權的應用工具,保護智慧產權權利人。透過這些多層數碼加封技術認証的數碼“印章或印記〞,將是本專利申請中的一個亮點。Many patent claims that apply to the invention of the wavefront are intended to address these issues; enhance the privacy and reliability of data cloud transmission and data cloud storage. Many of the data in the cloud can even be image or audio related. Since multiple sets of cloud transported or stored data are pre-processed on the client side, each set of cloud transport or cloud-stored data is a set of data that has been processed by wavefront over-conversion. These overwritten data are no longer the original data that can be interpreted. Therefore, the digital sealing method recommended in the application should give customers more confidence in the privacy and reliability of these cloud storage data, and this confidence no longer depends solely on the operator's first-hand ethics and integrity concerns. In the digital encapsulation method, known image, audio, or multimedia data can be used as a digital envelope as a means of promoting the storage and transportation of private and reliable cloud data. Most business opportunities are aimed at gaming and entertainment cloud communication applications. It can be used in a variety of digital goods copyright management and copy rights applications to protect intellectual property rights holders. The digital “seal or stamp” certified by these multi-layer digital sealing technologies will be a highlight of this patent application.

數碼圖像將被用來舉例說明本專利申請中的數碼加封/解加封技術。其它類型的數碼流可以被容易地結合於所提出的加封技術。Digital images will be used to illustrate the digital sealing/unsealing technique of this patent application. Other types of digital streams can be easily incorporated into the proposed sealing technique.

首先簡要的介紹及總結“寫〞和“讀〞過程的實施模式。 “寫〞的過程是利用一套波前覆用轉換來處理多組原始數據包括做為數碼信封的數碼圖像及數碼訊息,再將所產生覆用轉換後的數據存儲在雲端。“讀〞的過程是把存在雲端覆用轉換後的數據透過一套波前解覆用轉換來重構原始多組數碼圖像。數碼加封是在某些功能限制條件下的寫作方法,也是“寫〞過程的一套子集。這些數碼加封后的數據都會有某些原始數碼信封的特徵。 它應儲存某些原圖像特徵或其他特徵。這些功能限制條件是要保證數碼信封的特徵會出現下轉換後的多組數據中。數碼解加封是閱讀程式的一套子集,有從數碼加封后的數據重構原數碼訊息的功能。First, a brief introduction and summary of the implementation mode of the "write and read" process. “The process of writing is to use a set of wavefront overlay conversions to process multiple sets of raw data, including digital images and digital messages as digital envelopes, and then store the resulting transformed data in the cloud. "The process of reading 〞 is to reconstruct the original multi-group digital image by transforming the data that exists in the cloud over the set of wavefront decoding. Digital sealing is a writing method under certain functional constraints and a subset of the “writing process”. These digitally sealed data will have some of the characteristics of the original digital envelope. It should store some original image features or other features. These functional restrictions are to ensure that the characteristics of the digital envelope will appear in the converted multi-group data. Digital Decapsulation is a subset of the reading program that has the ability to reconstruct the original digital message from digitally sealed data.

數碼加封是波前覆用 的一組應用子集。其中波前覆用的多串輸入數碼檔案至少包括一串數據消息檔案和一串選定的數碼信封檔案。同時此一波前覆用的配置在透過所有多路輸入而定製加權和,必需保證它的多路輸出數據所顯現的外觀對人體自然感官而言與選定的數碼信封的圖像,視頻,或音頻格式的外觀是完全相同的。這類輸出檔案是加封后的或是有嵌入訊息的檔案。嵌入的訊息可以經由相應的波前解覆用處理器,在目的地把接收到的加封后檔案與已知的原數碼信封來進行復原運作。Digital seals are a subset of applications that are applied in wavefronts. The plurality of serial input digital files covered by the wavefront include at least one string of data message files and a series of selected digital envelope files. At the same time, this wave of pre-applied configurations is customized to weight the sum through all the multi-inputs, and it must be ensured that its multi-output data appears to the appearance of the human body with the selected digital envelope image, video, Or the appearance of the audio format is exactly the same. This type of output file is either a sealed file or an embedded message. The embedded message can be restored by the corresponding wavefront decoding processor at the destination with the received sealed file and the known original digital envelope.

總之,數碼加封/解加封可以透過波前覆用和波前解覆用運算來實現。波前覆用運作後的數據在數據雲傳輸和雲儲存方面的特色是有增的強隱私性和冗餘性。另一方面對波前覆用程式應用的冗餘性而言,數據加封是在相反方向的應用。數據加封在應用上是針對有限的接收用戶團隊,增強了加封后的數碼檔案隱私性,但最小化或完全犧牲了封后訊息數碼檔案的冗餘性。In short, digital sealing/unsealing can be achieved by wavefront override and wavefront cancellation. Wavefront-based data after operation is characterized by increased privacy and redundancy in data cloud transmission and cloud storage. On the other hand, for the redundancy of wavefront application applications, data sealing is applied in the opposite direction. Data encapsulation is applied to a limited receiving user team, enhancing the privacy of the digital file after the seal, but minimizing or completely sacrificing the redundancy of the digital file of the post-sealing message.

波前覆用/解複用處理功能是空間數字系統公司(SDS)在衛星通信領域的發明了;其中高難度的需求包括通信功率合成,安全性,可靠性和優化算法。 這套波前覆用/解覆用技術,除了體現了利用多維傳輸的通信架構,同時也發現此程式可用於超越衛星通信領域外其他領域的應用。其中一項這樣的應用是雲端的數據傳輸和數據存儲;數據的守密性,完整性和冗餘性是數據傳輸/存儲很重要的特徵。數碼加封和去加封可用於數據傳輸和數據存儲。它們可用於禮品和遊戲,如數碼幸運餅乾。在此申請書中我們將使用數據傳輸為例,如遞送郵件,說明的數碼加封和數碼解加封的概念。數碼解加封也可稱為數碼開封。The wavefront override/demultiplexing function is the invention of Space Digital Systems (SDS) in the field of satellite communications; the most difficult requirements include communication power synthesis, security, reliability and optimization algorithms. This wavefront overlay/disassembly technology not only embodies the communication architecture using multi-dimensional transmission, but also finds that this program can be used in applications beyond the field of satellite communications. One such application is data transmission and data storage in the cloud; data confidentiality, integrity and redundancy are important features of data transmission/storage. Digital sealing and de-sealing can be used for data transfer and data storage. They can be used for gifts and games such as digital fortune cookies. In this application we will use data transfer as an example, such as the delivery of mail, the concept of digital sealing and digital unsealing. Digital unsealing can also be called digital Kaifeng.

數碼加封/解加封技術的發明是關於透過雲把波前覆用轉換後的數據串發送到目的地;但不是發送全部的數據串而是發送經過篩選後的一部分覆用數據串。波前覆用轉換後的數據串又稱“覆用轉換數據串〞, 或稱“覆用數據串。〞一組加封后的數據流是透過波前覆用轉換與一組已知的數據串作為一套加封程式 的產物。 此組已知的數據串就是數碼信封,可以是發送方的個人圖像,用來表明誰正在發送的數碼加封的數據。不同的數碼信封也可能是顯示發送者複雜心情的不同圖片,同時發送的多組數據是可“罩〞 在不同數碼信封下的。在家庭成員間的通信,數碼信封可能是舊的數碼家庭錄像剪輯成新的數據流。所有的家庭成員都有舊視頻及剪輯後成的新數據流。The invention of the digital sealing/unsealing technique relates to transmitting a wavefront-converted data string to a destination through a cloud; but instead of transmitting all of the data strings, a filtered partial data string is transmitted. The wavefront overlay converted data string is also referred to as "overriding the converted data string" or "overriding the data string." A set of sealed data streams is transformed by a wavefront overlay with a set of known data strings. As a product of a set of sealing programs. The known data string for this group is a digital envelope, which can be the sender's personal image, which is used to indicate who is sending the digitally sealed data. Different digital envelopes may also be different pictures showing the sender's complex mood, and multiple sets of data sent at the same time can be "covered under different digital envelopes. In the communication between family members, digital envelopes may be the old digital home video clips into new data streams. All family members have old video and new data streams after editing.

波前覆用/解覆用在數碼加封應用領域內 可設定其他已知的數據流做為探測,認証,和標識功能信號。其中一套是先加封再存到IP雲方法包括︰先把多組第一數據在發送端轉換成多組數碼加封后的第二數據,其特徵在於所述每一組加封后的第二數據是經過所述所有多組第一數據的不同加權和; 然後再把所述加封后不同組的第二數據經由互聯網存儲到IP雲端。 同時也把多個連接到所述存儲加封后第二數據的不同鏈路存儲在所述的發送端。Wavefront Overlay/Unclave is used in the field of digital sealing applications. Other known data streams can be set as detection, authentication, and identification function signals. One of the methods is to first seal and then save to the IP cloud. The method includes: first converting the plurality of sets of first data into the plurality of sets of digitally sealed second data, wherein the set of the sealed second data is Is a different weighted sum of all the plurality of sets of first data; and then storing the sealed second set of second data to the IP cloud via the Internet. At the same time, a plurality of different links connected to the stored second data are stored at the transmitting end.

所述的數據處理方法,包括在發送端把多組第一數據集與一組已知數據轉換成多組數碼加封后的第二數據集,其中所述每組加封后的第二數據是由包括所有所述第一數據集的一組加權和;和在接收端從一些所述“罩〞在加封后第二數據集中還原成多組第三數據集和所述的一組已知數據集,其中所述的每一組第三數據是所有所述數碼加封后的多組第二數據集 的不同加權和。The data processing method includes: converting, at a transmitting end, a plurality of sets of first data sets and a set of known data into a plurality of sets of digitally sealed second data sets, wherein each of the set of sealed second data is Included with a set of weighted sums of all of the first data sets; and restored at the receiving end from some of the "masks" in a second data set after being sealed into a plurality of sets of third data sets and said set of known data sets And wherein each of said sets of third data is a different weighted sum of all of said plurality of digitally sealed sets of second data sets.

一套用於在IP雲儲存數據的方法,包括在發送端把多組第一數據集轉換成多組數碼加封后的第二數據集,其特徵在於所述每組加封后的每組第二數據是一張數據圖像由包括所有所述第一數據集的不同加權和所組成,每一張數據獨特外觀的強度主要是由一組所述的第一數據來控制。獨特外觀可以是圖像,聲音,以及對人體傳感器的其它特徵。A method for storing data in an IP cloud, comprising: converting, at a transmitting end, a plurality of sets of first data sets into a plurality of sets of digitally sealed second data sets, wherein each set of the second data after each set of sealed Is a data image consisting of different weighted sums including all of said first data sets, the intensity of the unique appearance of each piece of data being primarily controlled by a set of said first data. The unique appearance can be images, sounds, and other features of the human body sensor.

類似關於如何在利用數碼加封/解加封的技術數字版權管理領域的發明是包括在號為14/517717題為“數字版權管理和轉播的數碼加封〞的申請要求已申請過是於2014年10月17日提出之。原始數字檔案被稱為檔案的母版。其他副本都是子女版本; 每份子女版本都是透過與母版為數碼信封的數碼加封技術嵌入了獨特數碼及唯一標識檔案後而產生的。與某份子女版相關的獨特數碼標識只能與母版本同時透過解加封處理來恢復。出版和發行檔案只有子版本,同時母版本將被安全儲存。Similar to the invention in the field of digital digital rights management using digital sealing/unsealing technology is included in the number 14/517717 titled "Digital Rights Management and Broadcasting Digital Sealing Application Request has been applied in October 2014 Proposed on the 17th. The original digital file is called the master of the file. The other copies are child versions; each child version is created by embedding a unique digital and unique identification file with the master digital envelope technology for digital envelopes. A unique digital logo associated with a child's version can only be recovered with the parent version through the unwrapped process. Publication and distribution files are only sub-versions, and the parent version will be stored securely.

在數學上,某一件母版檔案用A來表示,它的一件x子版檔案用X來表示。此子版檔案獨特數碼標識檔案用Dx來表示。因為數碼加封絡處理是一種線性處理,x子版檔案X與其母版檔案A的關係涉及X = M * A + Dx,其中M是放大系數並應大於1。此關係的另一邊界條件是能使X的外觀對所有人體自然觀感的言與母版幾乎完全相同。 Dx的訊息是嵌入及隱藏在此子版數碼檔案X中,並且是不可能只單獨透過X檔案來恢復還原Dx。Mathematically, a master file is represented by A, and one of its x subversion files is represented by X. This sub-file unique digital identification file is represented by Dx. Since digital plus-encapsulation processing is a linear process, the relationship between the x-sub-file X and its master file A involves X = M * A + Dx, where M is the amplification factor and should be greater than one. Another boundary condition for this relationship is that the appearance of X is almost identical to the master of the human body. The Dx message is embedded and hidden in this sub-version digital file X, and it is impossible to restore the Dx only through the X file alone.

母版檔案A的另一件y子版檔案用Y來表示。此子版檔案獨特數碼標識檔案應用Dy來表示。Another y subversion file of the master file A is represented by Y. This sub-file is uniquely represented by the digital ID file application Dy.

為了要從一件子版檔案X中來恢復還原此子版檔案獨特數碼標識檔案Dx,此檔案X與其母版檔案A必需同時透過Dx= X - M * A的運算操作或同等運算過程來恢復還原此數碼標識檔案Dx。In order to restore and restore this sub-file unique digital identification file Dx from a sub-file X, this file X and its master file A must be restored by Dx= X - M * A operation or equivalent operation process. Restore this digital ID file Dx.

類似技術可以擴展到用於再廣播來提供附加訊息給觀眾。第一母版廣播檔案可用A來表示。第二廣播檔案B是一件透過加封處理後是嵌入或隱藏在子版廣播檔案X中。由於加封處理是一種線性處理,子版廣播文件X與母版廣播文件A的關系是根據X ​​= M * A + B,其中M是放大系數,並應根據大於1。此關係的另一邊界條件是能使X的外觀對所有人體自然觀感的言與母版幾乎完全相同。B是嵌入及隱藏在此子版數碼檔案X中的附加訊息檔案,並且是不可能只單獨透過字版廣播檔案X來恢復還原的第二廣播檔案。為了要從此子版數碼檔案X中來恢復還原附加訊息的第二廣播檔案B,此子版廣播檔案X與其第一母版廣播檔案A必需同時透過B = X- M * A的運算操作或同等運算過程來恢復還原此附加第二廣播檔案B。Similar techniques can be extended for rebroadcasting to provide additional messages to viewers. The first master broadcast file can be represented by A. The second broadcast file B is embedded or hidden in the sub-page broadcast file X after being processed by the seal. Since the seal processing is a linear processing, the relationship between the sub-broadcast file X and the master broadcast file A is based on X = M * A + B, where M is the magnification factor and should be greater than 1. Another boundary condition for this relationship is that the appearance of X is almost identical to the master of the human body. B is an additional message file embedded and hidden in this sub-version digital file X, and it is impossible to restore the restored second broadcast file only by the word broadcast file X alone. In order to restore the second broadcast file B of the restored additional message from the sub-digital file X, the sub-broadcast file X and its first master broadcast file A must simultaneously operate through B = X-M * A or equivalent. The operation process restores this additional second broadcast file B.

再廣播可能同時透過不同信道的,在不同的時間透過同一信道,或在不同的時間透過不同的信道。此技術可用於直播星(DBS),有線電纜,光纖,和其他無線或有線網路中的音頻或視頻廣播。嵌入或隱藏的檔案B可以是不同電視節目,機頂盒的持家數據,廣播到選定互聯網節點的網際網路數據,和/或其他數據。Re-broadcasting may pass through different channels simultaneously, through the same channel at different times, or through different channels at different times. This technology can be used for live or satellite (DBS), cable, fiber, and other audio or video broadcasts over wireless or wired networks. The embedded or hidden file B can be different television programs, housekeeping data for the set top box, internet data broadcast to selected internet nodes, and/or other data.

雲運算可讓某一用戶無論在何時何地都能拿到他或她所需要的檔案及應用程式, 讓用戶從他或她的桌面範圍仲介解放出來。本發明是關於如何使用數碼加封/解加封的技術增益在雲運算中獨利設備的數據隱祕性。由數碼加封技術嵌入的隱藏數據可以是數碼音頻,圖像,視頻,或其它數碼數據。我們在舉例說明中使用4至4 波前覆用來實現加封轉換,及引入定製加封/解加封轉換所需的其他已知數碼檔案及參數。Cloud computing allows a user to get the files and applications he or she needs whenever and wherever, freeing the user from his or her desktop context. The present invention relates to the use of digital encapsulation/decapsulation techniques to gain data privacy in a cloud computing operation. The hidden data embedded by digital sealing technology can be digital audio, image, video, or other digital data. In the illustration, we use 4 to 4 wavefronts to implement the seal conversion, and introduce other known digital files and parameters needed for custom seal/unpackage conversion.

當以下描述連同隨附圖式一起閱讀時,可更充分地理解本發明之態樣,該等隨附圖式之性質應視為說明性而非限制性的。該等圖式未必按比例繪製,而是強調本發明之原理。The invention will be more fully understood from the following description, taken in conjunction with the accompanying drawings. The drawings are not necessarily to scale, the

現描述說明性實施例。可另外或替代使用其他實施例。為節省空間或更有效地呈現,可省略顯而易見或不必要之細節。相反,可實施一些實施例而不揭示所有細節。Illustrative embodiments are now described. Other embodiments may be used in addition or instead. In order to save space or render more efficiently, obvious or unnecessary details may be omitted. Instead, some embodiments may be implemented without revealing all the details.

本發明利用一套有內置冗餘的M到-M波前覆用技術而產生的一組分佈式傳輸路徑或者存儲的系統與方法;其中M ³ 2也必須是整數。接在此波前覆用輸入口的M串數據流包括N串訊息數據流及額外的M-N串已知檔案數據流; 其中N ³ 1也是整數。這些 M串獨立的輸入數據流被波前覆用轉換成在複用領域中的M串輸出的波前分量(wfcs)。只有M串輸出中的M'串將被用於數據雲傳輸和/或數據雲儲存,其中M-N ≦ M'≦ M同時M'是一個整數。The present invention utilizes a set of distributed transmission paths or stored systems and methods that are generated with built-in redundant M to -M wavefront overlay techniques; where M 3 2 must also be an integer. The M-string data stream connected to the input port of the wavefront includes an N-string message data stream and an additional M-N-string known file data stream; wherein N 3 1 is also an integer. These M-string independent input data streams are converted by wavefront to the wavefront components (wfcs) of the M-string output in the multiplexed domain. Only the M' string in the M string output will be used for data cloud transmission and/or data cloud storage, where M-N ≦ M' ≦ M and M' is an integer.

此外,已知數據檔案流中的任何一串都可被選為數碼傳輸信封以及將用於一組M-到-M 波前覆用加封過程的一部分而進行處理。In addition, any of the known data archive streams can be selected as digital transmission envelopes and will be processed for use as part of a set of M-to-M wavefront overfill processes.

適當的權重或加權到一組M到-M 波前覆用處理器的多串輸入是選擇某串輸入為“載體〞運輸嵌入郵件的有效方法。 其M串輸出中至少有一串會被選定為加封后的數據檔案。 它的“載體〞就是被加權的數碼信封,同時對人體感官而言,它應當與原數碼信封有完全相同的外觀。這些相同的外觀包括從數據檔案獨特和易於與其他檔案區分的特徵。這些功能可以是直觀的圖片,視頻,音頻音樂,文字檔案,或多媒體檔案。Appropriate weighting or weighting to a set of M to -M wavefronts The processor's multi-string input is an efficient way to select a string of inputs as a "carrier" transport embedded message. At least one of the M string outputs will be selected as the sealed data file. Its "carrier" is a weighted digital envelope, and for the human sense, it should have exactly the same appearance as the original digital envelope. These same looks include features that are unique from the data file and easily distinguishable from other files. These features can be intuitive pictures, videos, audio music, text files, or multimedia files.

至少有一串加封后數據流將經由雲端被發送到目的地。此加封后的數據流在雲運輸或雲儲存中可能會顯示為數碼圖像,視頻剪輯,音樂剪輯,錄音,或數字卡通片。正如常規的信封的功能,這些數碼信封可以傳送上下文並嵌入郵件,意圖和作者的情緒預覽的作者,或者從嵌入式郵件傳來的訊息。At least one string of encrypted data will be sent to the destination via the cloud. This encrypted data stream may appear as digital images, video clips, music clips, audio recordings, or digital cartoons in cloud shipping or cloud storage. Just like the function of regular envelopes, these digital envelopes can convey context and embed messages, authors of authors and authors' emotional previews, or messages from embedded mail.

對人類器官而言 ,原數碼信封和加封后數碼流應具有完全相同的外觀,這些外觀識別及區分是靠人類聽覺器官,視覺器官,或同時兩類器官。For human organs, the original digital envelope and the digital stream after the seal should have exactly the same appearance. These appearances are identified and distinguished by human hearing organs, visual organs, or both types of organs.

在目的地的接收器應利用一套後處理器,如波前解複用,在原數碼信封的幫助下重建了嵌入的訊息數據。,原數碼信封必需是接收器的已知檔案, 或是可從其他通道獲知的數據串。The receiver at the destination should utilize a post-processor, such as wavefront demultiplexing, to reconstruct the embedded message data with the help of the original digital envelope. The original digital envelope must be a known file of the receiver, or a data string that can be learned from other channels.

本發明透過波前覆用及雲傳輸,如圖1所示,公開了對加封/解加封應用的經營理念,方法,和實施過程;類似的技術可以應用到視頻流,確保數據存儲服務隱私,確保檔案傳輸安全,以及透過網際網路雲的其他應用程式。本發明的實施例包括三項重要的領域,包括(1)在用戶端的前處理,即上述波前覆用,利用一選出的數碼信封對一件數碼信件加封; (2)把有嵌入郵件的封后數碼流送上的雲端,及(3)在用戶端的的後處理,即上述的波前解覆用,透過解加封來還原罩在數碼信封內的原數碼信件。我們將舉單一用戶為例說明預處理和後處理的操作概念。The present invention discloses the business concept, method, and implementation process of the sealing/unsealing application through wavefront overtaking and cloud transmission. As shown in FIG. 1, a similar technology can be applied to the video stream to ensure data storage service privacy. Ensure file transfer security and other applications that use the Internet cloud. Embodiments of the present invention include three important areas, including (1) pre-processing at the user end, that is, the above-mentioned wavefront override, using a selected digital envelope to seal a digital letter; (2) embedding an embedded message The cloud on the digital stream is sent, and (3) the post-processing on the user side, that is, the wavefront solution described above, and the original digital letter in the digital envelope is restored by de-sealing. We will use a single user as an example to illustrate the concept of pre- and post-processing operations.

在原理上,前處理和後處理都是在用戶段進行,並在用戶端的設備進行的。對於雲儲存,這些加封/解加封也可以在運營商的儲存設施及流程中進行。運營商可將匯總數據集透過雲端遠程網路分佈存儲在不同的雲儲存設施中。In principle, pre- and post-processing are performed in the user segment and on the user's device. For cloud storage, these seals/decapsulations can also be performed in the operator's storage facilities and processes. Operators can distribute aggregated data sets across different cloud storage facilities through cloud remote networks.

實施例1Example 1

圖1描述了在源頭的發送方和在目的地的接收方間的通信經營概念110。 發送寄件人利用一套在預處理130中2到2 波前覆用器來做加封處理,把一組訊息數據S(t) 嵌入到所選數碼信封E5(t)中。輸入的數據是用Word格式的英語片語“Open Sesame〞及其寫成4個中國字的 中文翻譯“芝麻開門〞及相關的讀音符號。所選擇的數碼信封是中國畫家,徐悲鴻,在1900年代初期作品中的一幅名畫“跑馬〞的數字圖片。另外在某一用戶社區在候選信封文檔180中有11個數碼信封公知給社區裡的所有用戶;包括這封信的發送方和接收方。有來自在預處理130中波前覆用器兩路輸出;  一路是將被送上雲端的封后數碼流Es(t) ,另一路被接地。在Es(t)是從兩個輸入數據檔案; S(t)和E5(t), 逐個像素處理的結果。波前覆用可利用一套2*2海大媽變換來做處裡器。 S(t)和E5(t)的幅度將被適當的“調整〞讓Es(t)及E5(t)的外觀對人類的器官而言完全相同; 如在一份美國專利申請書公開號碼2014 /0081989A1中仔細討論過的。。在這種情況下,在Es(t)中的跑馬似乎是E5(t)中同一跑馬的翻轉圖像。Figure 1 depicts a communication business concept 110 between a sender of a source and a receiver at a destination. The sender sends a set of message data S(t) into the selected digital envelope E5(t) using a set of 2 to 2 wavefront pre-processors in pre-processing 130. The input data is in the English-language phrase "Open Sesame〞 and its Chinese translation of 4 Chinese characters" in Sesame and the related pronunciation symbols. The digital envelope chosen was a Chinese painter, Xu Beihong, a digital painting of the famous horse in the early 1900s. In addition, in the user envelope, there are 11 digital envelopes in the candidate envelope document 180 that are known to all users in the community; including the sender and receiver of the letter. There are two outputs from the wavefront adder in the pre-processing 130; one is the sealed digital stream Es(t) that will be sent to the cloud, and the other is grounded. The Es(t) is the result of processing pixel by pixel from two input data files; S(t) and E5(t). Wavefront coverage can be done with a set of 2*2 sea aunt transforms. The magnitudes of S(t) and E5(t) will be appropriately "adjusted" so that the appearance of Es(t) and E5(t) is identical for human organs; as in a US patent application publication number 2014 It was discussed in detail in /0081989A1. . In this case, the horse in Es(t) appears to be a flip image of the same horse in E5(t).

對波前覆用後,Es(t)是一串封后數據流,它也是經由IP網路或雲端010發送到的目的地的唯一檔案。Es(t)外觀與在E5(t) 著名圖像中的奔馬在人類視覺感官上幾乎完全相同。在目的地,接收可以透過後處理140中的一套2*2 波前解覆用器或同等的處理器及原數碼信封來復原罩 在數碼信封內的訊息;“芝麻開門〞的英語短句, 中文短句及中文發音 寫在中國的嵌入式信;僅當提供給接收器的重新。整個操作過程包包括分別討論如下的三部分︰(1)預處理130,  (2)IP傳輸信道,IP雲端,或雲端010,以及(3)在雲下游的後處理140。After the wavefront is overwritten, Es(t) is a string of sealed data streams, which is also the only file sent to the destination via the IP network or cloud 010. The Es(t) appearance is almost identical to the running horse in the E5(t) famous image in human visual sense. At the destination, the receiver can restore the message enclosed in the digital envelope through a set of 2*2 wavefront de-splits or equivalent processors and original digital envelopes in post-processing 140; , Chinese phrases and Chinese pronunciations are written in China's embedded letters; only when provided to the receiver. The entire operational process package includes three parts discussed below: (1) pre-processing 130, (2) IP transport channel, IP cloud, or cloud 010, and (3) post-processing 140 downstream of the cloud.

預處理130︰Pre-processing 130..

在郵件加封或訊息加封的預處理中,可用一 套在預處理130中2至2 波前覆用器來做處理。它有兩串輸入; 一串是郵件數據 或訊息數據S(t), 另一串是所選擇的數碼信封或數碼加封串E5(t)。波前覆用轉換後也有兩路輸出數據串,即Es(t)和Ed(t),其中︰              Es(t) = S(t) + am* E5(t)                                           (1-1)              Ed(t) = S(t) + am* E5(t),                                          (1-2) 這裡的am >> 1是與圖像相關的放大系數,通常設定在5和30之間。In the pre-processing of mail or message encapsulation, a set of 2 to 2 wavefront pre-processors in pre-processing 130 can be used for processing. It has two strings of inputs; one string is mail data or message data S(t), and the other string is the selected digital envelope or digital envelope string E5(t). There are also two output data strings after the wavefront override, namely Es(t) and Ed(t), where: Es(t) = S(t) + am* E5(t) (1-1) Ed(t ) = S(t) + am* E5(t), (1-2) where am >> 1 is the magnification factor associated with the image, usually set between 5 and 30.

在一組2對2的海大媽矩陣(HM)中所有的矩陣元素都為“1〞或“-1〞。   此組矩陣可被選擇為一 套2至2 波前覆用的轉換或運算。公式(1-1)及(1-2)可以寫成矩陣形式為                             O = HM * I                                                                  (2)   這裡:           O = [O1, O2]T= [Es(t), Ed(t)]T (2-1)                       HM =(2-2)                       I =  [I1, I2]T =  [S(t), am*E5(t)]T (2-3)In a set of 2 to 2 sea aunt matrices (HM), all matrix elements are "1" or "-1". This set of matrices can be selected as a set of 2 to 2 wavefront overriding conversion operations. Equations (1-1) and (1-2) can be written in matrix form as O = HM * I (2) where: O = [O1, O2]T = [Es(t), Ed(t)] T (2 -1) HM = (2-2) I = [I1, I2] T = [S(t), am*E5(t)] T (2-3)

波前覆用器的端口通常被稱為“切片(slice)〞而其輸出端口被稱為是波前組件(wfc)。兩串輸入數據集S1(t) 和am* E5(t)分別連接到所述輸入端口,即在波前覆用器的切片1,切片2。同時另兩串輸出的數據串,即O1-O2,分別被連接到在預處理130中波前覆用器的輸出端口,即wfc1-wfc2。The port of the wavefront applicator is often referred to as a "slice" and its output port is referred to as a wavefront component (wfc). Two strings of input data sets S1(t) and am*E5(t) are respectively connected to the input port, that is, slice 1 and slice 2 of the wavefront prep. At the same time, the other two strings of output data, namely O1-O2, are respectively connected to the output ports of the wavefront coverr in the pre-processing 130, that is, wfc1-wfc2.

通常在一 套2到2 波前覆用處理器中會產生2組正交的波前向量或WFV的。  讓我們定義一組波前轉換系數wjk系數用來描述在預處理130中波前覆用器分發在第j行和k列的2維輸出向量。即O1,O2在預處理130中波前解覆用器的2維分量端口wfc1-wfc2,被定義為一組二維向量。它們是相互正交的。波前覆用器101的兩組WFVs是︰                WFV1= [w11,w21]T = [1,-1]T ,                      (3-1)              WFV2= [w21,w22]T = [1, 1]T ,                     (3-2)Usually two sets of orthogonal wavefront vectors or WFVs are generated in a set of 2 to 2 wavefronts. Let us define a set of wavefront conversion coefficients wjk coefficients used to describe the two-dimensional output vectors that the wavefront overlay distributes in the jth and kth columns in preprocessing 130. That is, O1, O2 in the pre-processing 130 the two-dimensional component ports wfc1-wfc2 of the wavefront de-emphasis are defined as a set of two-dimensional vectors. They are mutually orthogonal. The two sets of WFVs of the wavefront applicator 101 are: WFV1 = [w11, w21] T = [1, -1] T , (3-1) WFV2 = [w21, w22] T = [1, 1] T , (3-2)

S(t)和E5(t)是利用分別連接到在預處理130中波前覆用裝置的兩個輸入端口才能“附加〞到兩組正交波前上。 這兩組正交波前都用兩組波前向量(WFVs)來表示。每一波前向量(WFV)中的兩件分量都涉及到輸入和輸出端口號或(空間)序列的線性組合,但是它完全獨立於所述輸入和輸出數據集之外。S(t) and E5(t) are "attached" to the two sets of orthogonal wavefronts using two input ports respectively connected to the wavefront overlay in pre-process 130. Both sets of orthogonal wavefronts are represented by two sets of wavefront vectors (WFVs). The two components in each wavefront vector (WFV) involve a linear combination of input and output port numbers or (spatial) sequences, but it is completely independent of the input and output data sets.

波前覆用轉換的數學運算可以把一串數據分成數據塊, 再把不同數據塊中的若干位元組當成數字采樣, 然後再進行多組進及多組出的數碼操作。所有平行輸入的多組子數碼流一定要在波前覆用轉換輸入端口確定不同子數碼流采樣後的樣本是對齊的。數據的每個位元組可以視為一位數字采樣;也可把一數據串的X個位元組視為一位數字采樣。 譬如在某一串數碼流的數學運算中我們選了X=7,就意謂著此串數碼流中每7個位元組在波前覆用轉換的數學運算中會被視為一位數字采樣。,將被視為區塊一個數字號碼計算,波前覆用轉換。兩串7個位元組為數字采樣的數碼流可以接到一套2到2 波前覆用器的兩相應輸入端。 但此波前覆用器的兩相應輸出端必需採用X +1個位元組為采樣的大小單位以避免兩路輸出端的上溢和下溢問題。在這種情況下,每串輸出的數碼流都需用8個位元組的轉換運算。相對於7位元組的運算數據大小,該8位元組運算輸出形式結果會產生12.5%的額外開銷。另外在不同的實施例中,我們可以選擇99個位元組的采樣大小用於數學運算,即X =99位元組的運算數據大小,可減少運算的額外開銷到1%。The wavefront override conversion math operation can divide a string of data into data blocks, then treat several bytes in different data blocks as digital samples, and then perform multiple sets of multiple and multiple sets of digital operations. All sets of sub-digital streams input in parallel must be matched with the conversion input port on the wavefront to determine that the samples sampled by different sub-digital streams are aligned. Each byte of data can be treated as a single digit sample; the X bytes of a data string can also be treated as a single digit sample. For example, in the mathematical operation of a string of digital streams, we chose X=7, which means that every 7 bytes in the string of digital streams will be treated as a single digit in the mathematical operation of wavefront override conversion. sampling. , will be treated as a block number calculation, wavefront override conversion. Two strings of 7 bytes for digitally sampled digital streams can be connected to two corresponding inputs of a set of 2 to 2 wavefront pre-caps. However, the two corresponding outputs of the wavefront precoder must use X +1 bytes as the sampling size unit to avoid the overflow and underflow problems of the two outputs. In this case, each string of output digital streams requires a conversion operation of 8 bytes. The 8-bit operation output form result yields a 12.5% overhead relative to the 7-byte computed data size. In addition, in different embodiments, we can select the sampling size of 99 bytes for the mathematical operation, that is, the operation data size of X = 99 bytes, which can reduce the operation overhead to 1%.

在波前覆用轉換的線性組合或加權和的運算中,還有其他數據塊的選擇。譬如用於某些保留獨特的功能應用中的成像處理,以像素為單元的運算操作可能是更重要的。 也可能用一排或一列像素作為存儲運算的有效使用數據塊。There are other data block choices in the operation of the wavefront over-converted linear combination or weighted sum. For example, in some imaging processes that retain unique functional applications, pixel-based arithmetic operations may be more important. It is also possible to use a row or column of pixels as a valid use data block for the storage operation.

在本實施例中,只用兩路輸出中的一路傳送至目的地。預定的接收者必須有“更多訊息〞,以重新恢復罩在封后數碼流中的嵌入數碼訊息或數碼郵件; Word格式的英文短句“芝麻開門〞及其寫成4字的中文翻譯和發音。這組“更多訊息〞是指所選擇的原數碼信封。如果兩路輸出數據都能被傳遞到接收器,嵌入的郵件和所選擇的原數碼信封都可以在目的地透過這兩路數據被獨立地重新恢復而無需附加的任何已知訊息。In this embodiment, only one of the two outputs is transmitted to the destination. The intended recipient must have "more messages" to re-embed the embedded digital message or digital mail in the digital stream after the cover; the English short sentence in the word format "Sesame open door and its Chinese translation and pronunciation written in 4 words" . This group of "more messages" refers to the original digital envelope selected. If both output data can be passed to the receiver, both the embedded message and the selected original digital envelope can be independently restored at the destination through the two data without any additional known messages.

一般而言,從更高階的波前覆用轉換或多層加封的多條或多串輸出流中,這些封后數碼流至少要有一條或一串將透過IP雲端010被發送到目的地後處理140。嵌入郵件就是罩在這些串封后數碼流中的。更高階的波前覆用轉換通常被稱為N對N的波前覆用轉換;其中的N通常是在4和5000之間。將要發送到的目的地應當限制在少於NCR串封后數碼流。NCR總是一個比N小的整數。在沒有任何已知其他訊息的條件下, NCR串封后數碼流並沒有足夠的獨立訊息來重新組構罩在NCR串封后數碼流中的數碼訊息。In general, from a higher-order wavefront overlay conversion or a multi-layered multi-string or multi-string output stream, at least one or a string of these sealed digital streams will be sent to the destination through the IP cloud 010 for post-processing. 140. Embedding emails are covered in these serialized digital streams. Higher order wavefront overrides are often referred to as N-to-N wavefront overrides; where N is typically between 4 and 5000. The destination to be sent to should be limited to less than the NCR stringed digital stream. NCR is always an integer smaller than N. Without any other known information, the NCR serialized digital stream does not have enough independent messages to reconstruct the digital message over the NCR stringed digital stream.

雲端010︰Cloud 010..

只有一串波前覆用檔案從源頭透過雲端010送到目的地。原始的數碼信封對在源頭的發送方和在目的地接收方而言都是已知的數碼檔案。因此,給予Es(t)在雲端傳輸所需的信道帶寬大致與只傳輸嵌入的訊息S(t) 所需的信道帶寬相同。在那給予Es(t) 和對於S(t)在雲端傳輸所需頻帶的差可視為加封處理的開銷。Only a series of wavefront overlay files are sent from the source to the destination through the cloud 010. The original digital envelope pair is a known digital file for both the sender of the source and the recipient of the destination. Therefore, the channel bandwidth required to give Es(t) transmission in the cloud is roughly the same as the channel bandwidth required to transmit only the embedded message S(t). The difference in the frequency band required to transmit Es(t) and S(t) in the cloud can be regarded as the overhead of the sealing process.

後處理140︰Post processing 140..

後處理140是用於從雲端檢索後之數據,包括通過一套波前解覆用處理器,將該檢索後所接收的數據轉換為嵌入或隱藏之原數據檔案, 然後再將該原數據檔案的輸出。原始數碼信封檔案E5(t)是後處理140輸入數據之一,也要輸入到該套波前解覆用處理器中。從雲端檢索後所接收的數據應是先前存在雲端的波前覆用後數據。如果不被污染,基本上等於在預處理130中先前波前覆用處理後相應的輸出數據集,Es(t)。因此輸出的該原數據檔案可給予Es(t)或給予Es'(t)來表示。類似地,轉換成的嵌入或隱藏之原數據檔案是等於輸入數據S(t)的,因此可稱為S(t)或S'(t)的。The post-processing 140 is for retrieving data from the cloud, including using a set of wavefront decoding processors, converting the data received after the retrieval into an embedded or hidden original data file, and then converting the original data file. Output. The original digital envelope file E5(t) is one of the post-processing 140 input data and is also input to the set of wavefront decoding processors. The data received after retrieval from the cloud should be the pre-appreciation data of the pre-existing cloud. If not contaminated, it is substantially equal to the corresponding output data set, Es(t), after the previous wavefront is applied in the pre-processing 130. Therefore, the original data file outputted can be given to Es(t) or given to Es'(t). Similarly, the converted embedded or hidden original data file is equal to the input data S(t) and thus may be referred to as S(t) or S'(t).

根據公式(1-1); 可以透過所接收到的波前覆用後數據Es(t)和數碼信封E5(t) 來還原嵌入在封后數流中的隱藏訊息數據;           S(t) = Es(t) - am* E5(t)                                                  (4)According to the formula (1-1); the hidden message data embedded in the sealed stream can be restored by the received wavefront data Es(t) and the digital envelope E5(t); S(t) = Es(t) - am* E5(t) (4)

此處;am 參數可以透過實驗優化或透過已知的數碼檔案集來確定。因此,還可以根據公式(1-2)和公式(4) 重新構建在一套2對2波前覆用中所缺失的第二串輸出              Ed(t) = -Es(t) + 2*am* E5(t)                                   (5)Here; the am parameter can be determined experimentally or through a known digital archive set. Therefore, it is also possible to reconstruct the second series of outputs missing in a set of 2 to 2 wavefront overrides according to equations (1-2) and (4). Ed(t) = -Es(t) + 2*am * E5(t) (5)

一組2到2海大媽矩陣元素為“1〞或矩陣元素為“-1〞有可能被選為一套2至2 波前解覆用器 的運算。這些關係可以用矩陣形式寫出;             SM= HM* D                                                                  (6)     其中︰  D = [D1,D2]T =[Es(t),Ed(t)]T (6-1)                       SM = [S(t),am E5(t)]T (6-2)                     HM是公式 (2-2) 中的一組2對2 海大媽矩陣。A set of 2 to 2 sea aunt matrix elements is "1" or the matrix element is "-1" and may be selected as a set of 2 to 2 wavefront decompressors. These relationships can be written in matrix form; SM = HM* D (6) where: D = [D1, D2] T = [Es(t), Ed(t)] T (6-1) SM = [S( t), am E5(t)] T (6-2) HM is a set of 2 to 2 sea aunt matrices in equation (2-2).

波前解覆用器是在後處理140中。 它的的輸入端口被稱為波前分量(wfcs),即wfc1和wfc2,而且其輸出端口被稱為切片(slices),即slice1和slice2或切片1和切片2。 在這個後處理140中波前解覆用器例子中,輸入的2串數碼,即Es(t)和Ed(t),被分別的連接到它的輸入端口wfc1-wfc2。所重組回收的訊息數碼串,S1(t)是會從它的第一輸出端口輸出。通常情況下,在後處理140這種應用程式中波前解覆用器的第二輸出端口將是接地的。The wavefront decapper is in post processing 140. Its input ports are called wavefront components (wfcs), ie wfc1 and wfc2, and its output ports are called slices, ie slice1 and slice2 or slice 1 and slice 2. In this post-process 140 wavefront decomposer example, the input 2 string numbers, Es(t) and Ed(t), are connected to their input ports wfc1-wfc2, respectively. The reassembled message string, S1(t), is output from its first output port. Typically, the second output port of the wavefront de- hopper will be grounded in the post-processing 140 application.

作為選擇,從後處理140中波前解覆用器的第二輸出也可以用來重建另一份原數碼信封。這相應的副本將可與已知的數碼信封檔案比較,可做為檢驗所接收訊息數據的一項很好的完整性指標。如果比較結果顯示這兩件數碼信封不是相同的數字檔案,這就表示所接收到的封后數碼串已經在傳輸過程中被損害了。也就是說罩在封后數碼串內的訊息數據及重建後的訊息數據都有可能已經被損害了。Alternatively, the second output of the wavefront deblocker from post processing 140 can also be used to reconstruct another original digital envelope. This corresponding copy will be compared to known digital envelope files and can be used as a good indicator of integrity for verifying received message data. If the comparison shows that the two digital envelopes are not the same digital file, this means that the received digital string has been damaged during transmission. That is to say, the message data and the reconstructed message data in the sealed digital string may have been damaged.

圖1A和圖1B分別描繪了在候選信封第一子文檔180-1中的6件和在候選信封第二子文檔180-2中的5件候選數碼信封。  E5(t)被選擇用於在圖1的例子。 在圖1B的E11(t)是為一對發送者和接收者之間的私人通訊所選的一件共同已知的數碼檔案。1A and 1B depict 6 pieces in the candidate envelope first sub-document 180-1 and 5 pieces of candidate digital envelopes in the candidate envelope second sub-document 180-2, respectively. E5(t) is selected for the example in Figure 1. E11(t) in Figure 1B is a commonly known digital archive selected for private communication between a pair of senders and receivers.

圖2是在美國專利申請號13/953715與公開號20140081989圖5D 的複本。它是波前覆用/解覆用分別作為對雲數據存儲應用程式中的一個預處理和後處理之例子,旨在說明透過一套4-到-4 的波前覆用可把呈現的圖像存儲到分佈式的雲儲存中。波前覆用/解覆用可以透過任何一組正交矩陣或者一組非正交矩陣來做數字運算,只要其逆矩陣是存在的。這張圖中的第一列521示出了原始輸入的圖像,第二列522示出了波前覆用後再存儲的圖像或是波前覆用後等待被輸送的圖像,第三列523示出了在目的地經過解覆用後復原和恢復的圖像。在第一列521中的四張圖像是輸入到一套4-到-4 的波前覆用器的四幅圖像; 前3張是近期在紐約市布朗克斯動物園拍的,第一,第二和第三張照片,分別照是一張“鷹〞 以A1.png為標示,一張“虎〞以A2.png為標示,和一張“白頭動物〞以A3.png為標示。第四張是件經典作品由著名中國畫家徐悲鴻先生於1930年所畫的“奔馬〞。 “奔馬〞是 以A4.png為標示。Figure 2 is a copy of Figure 5D in U.S. Patent Application Serial No. 13/953,715 and Publication No. 20140081989. It is an example of wavefront override/union as a pre- and post-processing in a cloud data storage application, designed to illustrate the rendering of a rendered image through a set of 4-to-4 wavefront overlays. Like storage to distributed cloud storage. Wavefront overriding/unwrapping can be done numerically through any set of orthogonal matrices or a set of non-orthogonal matrices, as long as its inverse matrix is present. The first column 521 in this figure shows the original input image, the second column 522 shows the image stored after the wavefront is overwritten or the image waiting to be delivered after the wavefront is overwritten, the third column 523 shows an image restored and restored after the destination has been unwrapped. The four images in the first column 521 are four images that were input to a set of 4-to-4 wavefront overlays; the first three were recently taken at the Bronx Zoo in New York City, first. The second and third photos, respectively, are an "Eagle" marked with A1.png, a "Tiger is marked with A2.png, and a "White-headed animal is marked with A3.png." The fourth piece is a classic work by the famous Chinese painter Xu Beihong in 1930. "The running horse is marked with A4.png.

讓我們假設一組4到4海大媽變換為波前覆用矩陣。Let us assume that a group of 4 to 4 sea amas are transformed into wavefront override matrices.

是第二列522上的4 件波前覆用後檔案Ov,Ox,Oy,和Oz都有偽裝效果;這是原始的4 件輸入圖像在透過波前覆用轉換而創建的可存各種儲數據時已經分別的被加了不同權重。為了保證“奔馬〞畫的A1圖像是在4件波前覆用後檔案中更佔優勢的特徵來作為偽裝的,覆用轉換後像素強度是利用加權的A1圖像的條件下透過下列矩陣運算︰(7)It is the 4 pieces of wavefront-covered files Ov, Ox, Oy, and Oz on the second column 522 have camouflage effects; this is the original 4 pieces of input images created by wavefront overlay conversion. The data has been added with different weights. In order to ensure that the A1 image of the running horse is a more prevalent feature in the file after the four wavefront is applied, the converted pixel intensity is transmitted through the following matrix under the condition of weighted A1 image. Operation: (7)

其中am > 1 而且通常是被設定為大於10。還假定了4個輸入圖像中的像素的格子的尺寸已經完全相等。取決於偽裝圖像時,加權的權重選擇可應用於任何輸入之圖像。此外,公式(7)也可以等效地寫成︰(7-1)Where am > 1 and is usually set to be greater than 10. It is also assumed that the sizes of the grids of the pixels in the four input images are already completely equal. The weighted weight selection can be applied to any input image depending on the camouflage image. In addition, formula (7) can also be equivalently written as: (7-1)

因此,徐悲鴻的“奔馬〞畫成了參與覆用轉換的4件圖像中佔主導地位,奔馬的圖像並出現下所有4件波前覆用轉換後的數據裡,即Ov,Ox,Oy, 和Oz。其不同處在露面的奔馬圖像隨著不同的輸出圖像顯現出各種不同的亮度設定。Therefore, Xu Beihong's "Running Horse" paintings dominated the four images that participated in the conversion, and the images of the running horses appeared in the converted data of all four wavefronts, namely Ov, Ox, Oy. , and Oz. The different images of the running horses with different appearances show different brightness settings with different output images.

對封后的檔案圖像或外觀相對於所述數碼信封的外觀而言,其它的圖像運算如“翻面,旋轉,拉遠,或拉近〞是必需在波前覆用轉換前處理的。For the sealed archive image or appearance relative to the appearance of the digital envelope, other image operations such as "turning over, rotating, zooming in, or zooming in is necessary to be processed before the wavefront is overwritten. .

在圖像類比運算中為避免數據溢出和下溢,每個波前覆用後的數據(Ov,Ox,Oy, Oz)檔案設制約是原圖像A1-A4或復原後圖像(Sv,Sx,Sy,Sz )的2~3倍大小,。In order to avoid data overflow and underflow in the image analog operation, each wavefront data (Ov, Ox, Oy, Oz) file is restricted to the original image A1-A4 or the restored image (Sv, Sx, Sy, Sz) is 2 to 3 times larger.

第三列中的圖像透過一套閱讀過程而重組的圖像。 此“讀〞的過程也有兩個步驟。第一步包括從雲中分別下載所存的4 件波前覆用後的檔案。第二步是透過波前解複用轉換把4件 波前覆用後的檔案,如Ov,Ox,Oy, 和Oz,轉換成四件回收或再造的檔案Sv,Sx,Sy,和Sz。如果雲中所存的Ov,Ox,Oy, 和Oz沒有被污染,此四件再造的數碼檔案應當與波前覆用前的圖片A1 -A4幾乎相同。四個回收或再造均衡的圖像檔案然後可透過解均衡處理,轉換成4件回收的或重構的圖像基本上相當於四件各別的原始圖像A1~A4。The image in the third column is reorganized through a set of reading processes. This "reading process" also has two steps. The first step involves downloading the 4 pre-filtered files from the cloud. The second step is to convert four pre-filtered files, such as Ov, Ox, Oy, and Oz, into four pieces of recovered or reconstructed files Sv, Sx, Sy, and Sz through wavefront demultiplexing. If the Ov, Ox, Oy, and Oz stored in the cloud are not contaminated, the four reconstructed digital files should be almost identical to the images A1 - A4 before the wavefront is overwritten. The four recovered or reconstructed equalized image files can then be converted into four recovered or reconstructed images by de-equalization processing to substantially correspond to four separate original images A1 to A4.

假設所有四個檔案Ov,Ox,Oy, 和Oz都可用,波前解覆用轉換應遵循︰ .                                                      (8)                  其中,.                               (8-1)Assuming all four files Ov, Ox, Oy, and Oz are available, the wavefront solution conversion should follow: (8) Among them, . (8-1)

更明確地說,在4件重構的圖像(Sv,Sx,Sy,Sz)的每一件圖像中的每個像素強度都是一組各圖像相對像素亮度的線性組合的結果。 這相對像素是指在四件波前覆用後的圖像檔案的相同行和列的格子。例如,在Sv,Sx,Sy,和Sz重組或恢復圖像中第41行和第51列的格子的單像素強度是由4件波前覆用後圖像Ov,Ox,Oy, 和Oz中每件的第41行第51列的單像素強度乘以各自的權重參數的加權和。More specifically, each pixel intensity in each of the four reconstructed images (Sv, Sx, Sy, Sz) is the result of a linear combination of the brightness of a set of images relative to the pixel. This relative pixel refers to the grid of the same row and column of the image file after the four wavefronts are overwritten. For example, in Sv, Sx, Sy, and Sz, the single-pixel intensity of the lattice of the 41st and 51st columns in the reconstructed or restored image is composed of 4 pieces of wavefront-coated images Ov, Ox, Oy, and Oz. The single pixel intensity of row 41, column 51 of each piece is multiplied by the weighted sum of the respective weighting parameters.

用於加封應用中,在源頭的 4串波前覆用後檔案只有一串是由發送方透過雲發送到目的地。作為一個例子中,A 1可以是訊息數據透過雲端被傳遞到目的地,而A4是選定的數碼信封。對發送方和在目的地的接收方而言 A2,A3和A4都是先驗驗過的已知數碼。In the seal application, only one string of the file is overwritten by the sender through the cloud to the destination. As an example, A 1 may be that message data is delivered to the destination through the cloud, and A4 is the selected digital envelope. For the sender and the receiver at the destination, A2, A3 and A4 are known digits that have been tested first.

在第二列522的4件檔案中的任何一件都可用做封后數碼串, 它可透過雲端來傳達嵌入其內的數碼訊息(A1)。讓我們選擇Ov做被運送到目的地的封后數碼串或稱為加封后的數據檔案。很顯然,加封后的數據檔案Ov顯現阿的是一覆正在奔跑的一匹馬的圖像。這圖像與數碼信封A4上的奔馬的圖像基本上是相同的。封后數碼串或加封后的數據檔案Ov中罩有A1數碼訊息的,也是一件透過雲端被發送到目的地的檔案。Any of the four files in the second column 522 can be used as a sealed digital string, which can communicate the digital message embedded in it (A1) through the cloud. Let us choose Ov to do the post-sequence digital string that is shipped to the destination or to be called the sealed data file. Obviously, the sealed data file Ov shows an image of a horse that is running. This image is basically the same as the image of the running horse on the digital envelope A4. The sealed digital string or the sealed data file Ov is covered with A1 digital information, and is also a file that is sent to the destination through the cloud.

我們在這裡不再重複對此幅圖表所述圖像處理的所有數學細節。總之,我們利用上述相同的數學運算用於為數碼訊息加封,或嵌入將會經由雲中運輸的郵件到數碼信封內。我們要展示波前覆用在加封/解加封應用的兩個重要特徵。在加封處理過程中被選定的數碼信封(A4)後; 1.    選定的訊息A1被嵌入在所選擇的加封數據(Ov) 中。加封數據或稱封后數碼,封后數碼串,封后數據。 2.    對人類感官而言,原始數碼信封A4和封后數碼串或封后數據檔案(Ov)應顯現出現相同的特徵,並且這些相同特徵可清晰從其他的數碼檔案(A2,A3和A1)中分辨出。 3.    A2和A3可能成為驗証或識別的數碼檔案。We will not repeat all the mathematical details of the image processing described in this chart here. In summary, we use the same mathematical operations described above to seal digital messages or embed messages that will be transported via the cloud into digital envelopes. We want to show two important features of wavefront application in the sealing/unsealing application. After the selected digital envelope (A4) during the sealing process; 1. The selected message A1 is embedded in the selected seal data (Ov). Seal the data or the digital after sealing, seal the digital string, and seal the data. 2. For human senses, the original digital envelope A4 and the sealed digital string or the sealed data file (Ov) should appear to have the same characteristics, and these same features can be clearly seen from other digital files (A2, A3 and A1) Distinguished in. 3. A2 and A3 may become digital files for verification or identification.

在另一種方案中,其中A 1是設定為數碼訊息將經由雲端傳送到目的地的數據,A2和A3可用來進行驗証,和A4為選定的數碼信封,Ov和Oz是兩串將發送到雲端的封后數碼串。在目的地,第一位閱讀者已拿到三件數據A2,A3,和A4的數碼檔案,所以只需要收到兩串封后數碼串Ov或Oz中的一串即可恢復還原嵌入在封后數碼串內的數碼訊息圖像,Sv。對第一讀者而言,能注意到而且利用到有冗餘的波前覆用映像處理,關注到這一點是很重要的。恢復還原的數碼訊息圖像Sv應當與原數碼訊息圖像A1完全相同。在另一方面,第二閱讀者並沒有拿到選定為數碼信封 “奔馬〞 A4的數碼檔案,但已有另兩件檔案A2和A3的原始數碼檔案,所以必需要同時收到透過雲端下載來的兩串封后數碼串Ov和Oz,才能恢復複還嵌入在封后數碼串內的數碼訊息圖像A1。對第二讀者而言,他也可利用這兩串下載的封后數碼串來恢復還原數碼信封的數碼檔案, 為未來解加封處理做準備。關注到這一點也是很重要的。In another scenario, where A 1 is set to data that the digital message will be transmitted to the destination via the cloud, A2 and A3 can be used for verification, and A4 is the selected digital envelope, and Ov and Oz are two strings that will be sent to the cloud. The sealed digital string. At the destination, the first reader has obtained three pieces of data A2, A3, and A4 digital files, so only need to receive a string of two strings of digital strings Ov or Oz to restore and embed in the package. Digital message image in the post-digital string, Sv. It is important for the first reader to be aware of this and to take advantage of redundant wavefront overlay image processing. The restored digital message image Sv should be identical to the original digital message image A1. On the other hand, the second reader did not get the digital file selected as the digital envelope "Ben Ma A4, but there are two other files A2 and A3 original digital files, so you must also receive the download through the cloud. The two strings of digital IDs Ov and Oz can restore the digital message image A1 embedded in the sealed digital string. For the second reader, he can also use the two series of downloaded digital strings to restore the digital file of the digital envelope to prepare for the future unsealing process. It is also important to pay attention to this.

對於第三種情況,其中A1,A2和A3是將要透過雲發送到目的地的三件數碼檔案(A1是數碼訊息), A4作為選擇數碼信封,Ov,Ox,Oz是被發送到雲端的三串封后數碼串。在目的地,第一位讀者已拿到的原數碼檔案中只有數碼信封A4,所以需要從雲端中收到所有3串封后數碼串Ov,Ox,Oz後,才能恢復複還嵌入在封后數碼串內的數碼訊息圖像,Sv。注意到,對第一讀者而言這裡的波前覆用映像處理是沒有冗餘的,這點是很重要的。在另一方面,第二閱讀者已拿到的原數碼檔案中沒有數碼信封“奔馬〞A4。他可以從雲端下載三串封后數碼串Ov,Ox,Oz但他將無法重建嵌入的訊息圖像A1。For the third case, where A1, A2, and A3 are three digital files that will be sent to the destination through the cloud (A1 is a digital message), A4 is selected as a digital envelope, Ov, Ox, and Oz are sent to the cloud. Serial string after string. At the destination, the first digital file that the first reader has obtained is only the digital envelope A4, so it is necessary to receive all the three strings of digital IDs Ov, Ox, Oz from the cloud before they can be restored and re-embedded. Digital message image in the digital string, Sv. It is important to note that for the first reader, the wavefront overlay image processing here is not redundant. On the other hand, the second digital reader has not received a digital envelope in the original digital file "Running Horse A4. He can download the three-string digital string Ov, Ox, Oz from the cloud but he will not be able to reconstruct the embedded message image A1.

對於第四種情況,其中A1,A2和A3是將要透過雲發送到目的地的三件數碼檔案(A1是數碼訊息)是數據集透過雲發送到目的地,A4作為選擇數碼信封,Ov,Ox,Oy,Oz是被發送到雲端的四串封后數碼串。在目的地,第一位讀者已拿到的原數碼檔案中只有數碼信封A4,所以只需要從雲端四串封后數碼串Ov,Ox,Oy,Oz中收到任何3串封后數碼串,就能恢復複還嵌入在封后數碼串內的數碼訊息圖像,Sv。對第一讀者而言這裡的波前覆用映像處理是有冗餘的,這點是很重要的。在另一方面,第二閱讀者已拿到的原數碼檔案中沒有數碼信封“奔馬〞A4。他必從雲端下載三串封后數碼串Ov,Ox,Oz但他將無法重建嵌入的訊息圖像A1。在另一方面,第二閱讀器不具備數字“馬〞A4和他必須透過雲下載所有四串封后數碼串後才能重建嵌入的圖像中A1。對第二讀者而言這裡的波前覆用映像處理是沒有冗餘的,這點是很重要的。For the fourth case, where A1, A2 and A3 are three digital files to be sent to the destination via the cloud (A1 is a digital message) is the data set sent to the destination via the cloud, A4 as the selection digital envelope, Ov, Ox Oy, Oz is a four-string digital string that is sent to the cloud. At the destination, the first digital file that the first reader has obtained is only the digital envelope A4, so only need to receive any 3 strings of digital strings from the cloud series of digital strings Ov, Ox, Oy, Oz. It is possible to restore the digital message image embedded in the sealed digital string, Sv. For the first reader, the wavefront overlay image processing here is redundant, which is very important. On the other hand, the second digital reader has not received a digital envelope in the original digital file "Running Horse A4. He will download the three-string digital string Ov, Ox, Oz from the cloud but he will not be able to reconstruct the embedded message image A1. On the other hand, the second reader does not have the number "Ma Ying A4 and he has to download all four strings of digital strings through the cloud to reconstruct A1 in the embedded image. For the second reader, the wavefront overlay image processing here is not redundant, which is very important.

實施例2Example 2

圖3描繪了使用上述波前覆用技術為兩組加封數碼訊息的操作概念。有三個部分︰(1)預處理130或加封,(2) 透過雲端010傳送,以及(3) 後處理140或解加封或開封。與在圖1所示的那套操作概念相比是幾乎相同的。圖3功能的技術是來發送一串數碼訊息數據S(t)和一串原數碼信封E5(t)到一組指定的接收器。預處理130的兩串輸出信號Es(t)和Ed(t)都會發送到接收端。Figure 3 depicts the operational concept of adding digital messages to two groups using the wavefront overlay technique described above. There are three parts: (1) pre-processing 130 or encapsulation, (2) transmission through cloud 010, and (3) post-processing 140 or de-seal or unsealing. It is almost the same as the set of operational concepts shown in Figure 1. The technique of Figure 3 is to send a string of digital message data S(t) and a string of original digital envelopes E5(t) to a specified set of receivers. The two series of output signals Es(t) and Ed(t) of the pre-processing 130 are sent to the receiving end.

一則消息會被隱祕的嵌入在兩串加封后的數據檔案Es(t)和Ed(t)裡, 再由源頭髮送到在目的地的接收器。接收器利用這兩串加封后的數據檔案恢復重構嵌入的數碼訊息和原數碼信封。 此原數碼信封可被用於在發送器和接收器之間的後續傳輸。雲通信信道兩側的發送方與接收方一旦數碼信封數據變為已知的,發送方只需把兩串波前覆用後的檔案中的一串,或是Es(t)或是Ed(t)的發送到雲端,接收方就可以恢復重構嵌入的數碼訊息S(t)。A message is secretly embedded in the two strings of sealed data files Es(t) and Ed(t), which are then sent by the source to the receiver at the destination. The receiver recovers the embedded digital message and the original digital envelope using the two strings of sealed data files. This original digital envelope can be used for subsequent transmissions between the transmitter and the receiver. The sender and the receiver on both sides of the cloud communication channel, once the digital envelope data becomes known, the sender only needs to string one of the two pre-filtered files, or Es(t) or Ed ( When t) is sent to the cloud, the receiver can recover the reconstructed embedded digital message S(t).

圖3提供了一種方法來同時發送一組數碼訊息數據和一串原始的數碼信封數據給所期望的設定接收器。   預處理130的兩個輸出,Es(t)的和Ed(t)的信號同時發送給接收器,可用於重構嵌入的數碼訊息數據,及該數碼信封的原數據。Figure 3 provides a method to simultaneously transmit a set of digital message data and a string of raw digital envelope data to a desired set receiver. The two outputs of the pre-processing 130, the Es(t) and Ed(t) signals are simultaneously transmitted to the receiver, which can be used to reconstruct the embedded digital message data and the original data of the digital envelope.

實施例3Example 3

圖4示出使用一套2到2 波前覆用透過兩層順序加封設定為一組訊息數據做雙加封的發送 (Tx)經營理念。它示出了圖1中三段設定的前兩段。圖1中三段設定︰(1) 預處理130或加封處理,(2) 透過雲端010傳送,和(3) 後處理140或解加封處理或開封處理。Figure 4 shows the transmission (Tx) business philosophy of using a set of 2 to 2 wavefronts to double-seal a set of message data through a two-layer sequential seal. It shows the first two segments of the three segments set in Figure 1. The three stages in Figure 1 are set: (1) pre-processing 130 or sealing processing, (2) transmission through cloud 010, and (3) post-processing 140 or de-seal processing or unsealing processing.

此處有兩套圖 4中的加封處理串聯在一起。,每一套加封處理都是與圖1中所示的加封處理相同的。  在所述第一預處理130-1,有兩個輸入端; S(t)和E1(t)和一個輸出端x(t)的。第二輸出端被接地。 S(t) 是透過雲端交付到目的地的數碼訊息包括一句英文片語“芝麻開門〞和它的中國翻譯並發音符號。 E1(t)是一件從候選信封文檔180中選定一件內數嗎信封,並且第一預處理130-1的第一輸出端x(t)的功能之一是與E1(t)的外觀對人類感官而言基本上完全相同。他的第二輸出端被接地了。Here, two sets of sealing processes in Figure 4 are connected in series. Each set of sealing process is the same as the sealing process shown in FIG. In the first pre-processing 130-1, there are two inputs; S(t) and E1(t) and one output x(t). The second output is grounded. S(t) is a digital message delivered to the destination through the cloud, including an English phrase "Sesame Open Door and its Chinese translation and pronunciation symbols. E1(t) is an envelope selected from the candidate envelope document 180, and one of the functions of the first output x(t) of the first pre-processing 130-1 is the appearance with E1(t) It is basically the same for human senses. His second output is grounded.

在所述第二預處理130-2,也有兩個輸入端中,x(t)和E5(t)和只有一個輸出Es(t)。 E5(t) 也是從候選信封文檔180中選出的,是做為所選擇的外數碼信封,第二預處理130-2的第一輸出端的功能之一是Es(t)的的外觀與E5(t)的外觀上對人類感官而言基本上完全相同。In the second pre-processing 130-2, there are also two inputs, x(t) and E5(t) and only one output Es(t). E5(t) is also selected from the candidate envelope document 180 as the selected external digital envelope. One of the functions of the first output of the second preprocessing 130-2 is the appearance of Es(t) and E5 ( The appearance of t) is essentially identical to human senses.

用於傳輸的數碼檔案Es(t) 的外觀上沒有出現一句 “芝麻開門〞 的英文短句和它的四字中文翻譯及發音符號。在適當選擇的E1(t)或E5(t)的條件下傳輸封后數碼檔案Es(t)所需的帶寬應與透過雲只發送S(t)的時接近相同。The appearance of the digital file Es(t) used for transmission does not appear in the sentence "Sent of sesame opening English sentences and its four-character Chinese translation and pronunciation symbols. The bandwidth required to transmit the sealed digital file Es(t) under appropriately selected E1(t) or E5(t) should be approximately the same as when the S(t) is transmitted through the cloud.

在其他實施方案中,各種圖像處理步驟為了不同的目可先用於數碼信封上,如縮小單像素中的動態範圍,或簡單地在波前覆用前為增強加封檔案的可驗証性和可鑑定性。許多預先圖像處理過的數碼圖像可存儲在數碼信封候選檔案中作為候選數碼信封。當然,這些額外的先處理可以包括在圖1中作為預處理130的一部分 。這些額外的先處理也可用於在圖4雙加封的第一預處理130-1或第二預處理130-2中任一套,或透過兩套第一預處理130-1及第二預處理130-2來實現。In other embodiments, various image processing steps may be used for digital envelopes for different purposes, such as reducing the dynamic range in a single pixel, or simply verifying the verifiability of the archived file before the wavefront is overwritten. Identifiability. Many pre-image processed digital images can be stored in the digital envelope candidate file as candidate digital envelopes. Of course, these additional pre-processing can be included as part of the pre-processing 130 in FIG. These additional pre-processings can also be used in either the first pre-processing 130-1 or the second pre-processing 130-2 double-sealed in Figure 4, or through two sets of first pre-processing 130-1 and second pre-processing. 130-2 to achieve.

圖5示出使用兩層2對2 波前解覆用方法順序地經由接收器(Rx)設定解雙加封數碼訊息的操作概念。它描述了圖1中三段操作的最後兩段。 圖1中的三段操作分別是 (1)預處理130或加封處理,(2) 透過雲端010傳送,和(3) 後處理140或解加封處理或開封處理。Figure 5 illustrates the operational concept of sequentially setting a double-encapsulated digital message via a receiver (Rx) using a two-layer 2-to-2 wavefront de-spreading method. It describes the last two segments of the three operations in Figure 1. The three operations in Figure 1 are (1) pre-processing 130 or encapsulation processing, (2) transmission through cloud 010, and (3) post-processing 140 or de-seal processing or unsealing processing.

操作概念是由兩串解加封處理的串聯所組成。每一串是與圖1所示的去加封處理相同。在以打開外數碼信封中所述第一後處理140-1中,有兩個輸入端分別結入Es(t)和E5(t)數碼串;和一個輸出端輸出x(t) 數碼串的。第二輸出端被接地。 Es(t)是在目的地的接收器接收到的數碼數據檔案。此數碼檔案含有嵌入的數碼訊息。 E5(t)是一件已知的數碼信封檔案。是從發送方和接收方都已認可的候選信封文檔180選出的外層數碼信封。The operational concept consists of a series of two-string unwrapped processing. Each string is the same as the de-sealing process shown in FIG. In the first post-processing 140-1 described in the opening of the external digital envelope, two inputs are respectively connected to the Es(t) and E5(t) digital strings; and one output is outputting the x(t) digital string. . The second output is grounded. Es(t) is the digital data file received at the receiver of the destination. This digital file contains embedded digital messages. E5(t) is a known digital envelope file. An outer digital envelope selected from the candidate envelope document 180 that has been approved by both the sender and the recipient.

第一串輸入Es(t)是一組在目的地的所期望接收器中接收到的數碼檔案,並應基本上等於圖4所述第二預處理130-2的唯一輸出。它的外觀, 對人類感官而言,應與E5(t)的外觀完全相同。同樣地對人類感官而言,第一後處理140-1的第一輸出端輸出的一串x(t)數據串而它的第二輸出端被接地了。在第二後處理140-2也有兩個輸入端,分別接入了一串x(t) 數據串和一串E1(t) 數據串。x(t)的功能外觀基本上應與E1(t) 外觀的相同。E1(t)是為所選擇的內層數碼信封,是從發送方和接收方都已認可的候選信封文檔180中選出的。在第二後處理140-2只有一個輸出端輸出一串S(t) 數據串;應是復原的嵌入數碼訊息, 包括一句 “芝麻開門〞的英文短句,其4字的中文翻譯及發音。The first string of inputs Es(t) is a set of digital archives received at the desired receiver of the destination and should be substantially equal to the unique output of the second pre-process 130-2 as described in FIG. Its appearance, for human senses, should be identical to the appearance of E5(t). Similarly for human senses, a string of x(t) data strings output by the first output of the first post-processing 140-1 and its second output are grounded. The second post-processing 140-2 also has two inputs that respectively access a string of x(t) data strings and a string of E1(t) data strings. The functional appearance of x(t) should be essentially the same as the appearance of E1(t). E1(t) is the selected inner layer digital envelope that is selected from the candidate envelope documents 180 that have been approved by both the sender and the recipient. In the second post-processing 140-2, only one output terminal outputs a string of S(t) data strings; it should be a restored embedded digital message, including a sentence of "Sinus opening English short sentence, its 4-word Chinese translation and pronunciation.

實施例4Example 4

圖6描述了使用更高階波前覆用轉換的技術,用於在發送端(Tx)封裝郵件數據加封的經營理念。一套高階波前覆用是利用一組M-至-M 波前覆用; 其中M是大於或等於4 的整數。我們舉一個4到4 波前覆用作為加封/解加封操作概念的例證。加封/解加封的三段分組是與圖1中所示的相同︰ (1) 預處理630或加封處理, (2)透過雲端010傳送,以及(3)後處理640或解加封處理。它示出了上述的前兩段。Figure 6 depicts the technique of using a higher-order wavefront override conversion technique for encapsulating mail data at the transmitting end (Tx). A set of high-order wavefront overrides is overridden by a set of M-to-M wavefronts; where M is an integer greater than or equal to 4. Let's take a 4 to 4 wavefront overlay as an example of the concept of a seal/unfill operation. The three-packet of the seal/unpackage is the same as that shown in Figure 1. (1) pre-processing 630 or encapsulation processing, (2) transmission through cloud 010, and (3) post-processing 640 or de-encapsulation processing. It shows the first two paragraphs above.

在預處理630中的一套4到4 波前覆用器有四個輸入端和四條輸出端。輸入端分別連接到S(t),E10(t),E1(t)和E5(t)。輸出端僅輸出一串Ex(t)而其餘三個輸出端接地。 S(t)包括一句 “芝麻開門〞 的英文短句和它的四字中文翻譯及發音,而且是將透過雲端交付給目的地的數碼訊息。 E5(t) 是由候選信封文檔180中所選出的數碼信封。覆用器的第一輸出Ex(t) 與所選擇的數碼信封E5(t)的外形對人類感官而言基本上完全相同。所述接在第二和第三輸入端的兩串數碼串E10(t)和E1(t)的也是由候選信封文檔180中所選出的數碼檔案。對發送方及接收方而言候選信封文檔180中的數碼檔案都是已知的。A set of 4 to 4 wavefront pre-processors in pre-processing 630 has four inputs and four outputs. The inputs are connected to S(t), E10(t), E1(t) and E5(t), respectively. The output only outputs a string of Ex(t) and the remaining three outputs are grounded. S(t) includes a sentence saying “The essay opens the English short sentence and its four-character Chinese translation and pronunciation, and it is a digital message that will be delivered to the destination through the cloud. E5(t) is the digital envelope selected by the candidate envelope document 180. The shape of the first output Ex(t) of the overlay and the selected digital envelope E5(t) are substantially identical for human senses. The two strings of digital strings E10(t) and E1(t) connected to the second and third inputs are also digital files selected by the candidate envelope document 180. The digital files in the candidate envelope document 180 are known to both the sender and the recipient.

當我們用一套4到4海大媽矩陣為對波前覆用的轉換運算,覆用轉換的數學推導是與那些在圖2中的相同 。在預處理630中的此套4至4在波前覆用的運算是基於公式(7)而寫成;(7-2)When we use a set of 4 to 4 sea aunt matrices as the conversion operations for the wavefront, the mathematical derivation of the overriding transformation is the same as those in Fig. 2. The operation of the sets 4 to 4 in the pre-processing 630 in the wavefront is written based on the formula (7); (7-2)

圖6中的第一輸出O1被命名為Ex(t),另外3個輸出端是接地的。放大因子am被設定為約10,其結果使Ex(t) 的外形在透過雲端010被傳遞到目的地的過程中,對人類感官而言,基本上與E5(t)的的外形完全相同。The first output O1 in Figure 6 is named Ex(t) and the other three outputs are grounded. The magnification factor am is set to about 10, and as a result, the shape of Ex(t) is transmitted to the destination through the cloud 010, and is substantially identical to the shape of the E5(t) for the human sense.

圖7是一幅在目的地為解加封處理的框圖,也是圖6的反轉處理圖。描述了使用高階波前解覆用技術為一串封后數碼串透過解加封轉換而還原罩在其中的訊息數碼的接收(Rx) 經營理念。一套高階波前解覆用是利用一組M-至-M 波前解覆用的運算; 其中M是大於或等於4的整數。加封/解加封的三段分組是與圖1中所示的相同︰ (1) 預處理630或加封處理,(2)透過雲端010傳送,以及(3)後處理640或解加封處理。此圖示出了上述的後兩段。Fig. 7 is a block diagram showing the decapsulation process at the destination, and also the inversion processing diagram of Fig. 6. Describes the use of high-order wavefront de-embedding techniques to reduce the received digital (Rx) business philosophy of a string of digital strings after de-encapsulation conversion. A set of high-order wavefront solutions is an operation that uses a set of M-to-M wavefront solutions; where M is an integer greater than or equal to 4. The three-packet of the seal/unpack is the same as that shown in Figure 1. (1) pre-processing 630 or encapsulation processing, (2) transmission through cloud 010, and (3) post-processing 640 or de-seal processing. This figure shows the last two paragraphs above.

在目的地只能收到一串透過雲端010發送到的封后數碼串。其餘三串已在發送端被接地了。當適當地選擇數碼信封E5(t)並進一步做相應優化預處理630,此串封后數碼串所需的通信信道帶寬可以是與S(t)的信號本身帶寬幾乎相同。Only a string of sealed digital strings sent through the cloud 010 can be received at the destination. The remaining three strings have been grounded at the sender. When the digital envelope E5(t) is properly selected and further optimized pre-processed 630, the bandwidth of the communication channel required for the serialized digital string may be almost the same as the bandwidth of the signal itself of S(t).

在後處理640 中的一套4對4 波前解覆用有四個輸入端;  分別接入Ex(t), E10(t), E1(t), 及E5(t).  其中(1) Ex(t)是唯一接收到的封后數碼串,(2) E10(t)是候選信封文檔180中的一件已知的數碼數據,(3) E1(t) 是候選數碼信封檔案180中的另一件已知的數碼數據,和 (4) E5(t) 是從候選數碼信封檔案180中選出的已知的數碼信封。對發送方及接收方而言,候選數碼信封檔案180的每一件數碼檔案都是已知的。根據公式(7-2);                Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t)                     (8)       和   S(t)= Ex(t)  (am* E5(t)+ E1(t)+ E10(t))                   (8-1)A set of 4 to 4 wavefront solutions in post-processing 640 has four inputs; respectively, accessing Ex(t), E10(t), E1(t), and E5(t). (1) Ex(t) is the only received digital string that is received, (2) E10(t) is a piece of known digital data in the candidate envelope document 180, and (3) E1(t) is the candidate digital envelope file 180. Another known digital data, and (4) E5(t) is a known digital envelope selected from the candidate digital envelope file 180. Each digital file of the candidate digital envelope file 180 is known to both the sender and the recipient. According to the formula (7-2); Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t) (8) and S(t)= Ex(t) (am* E5(t)+ E1(t)+ E10(t)) (8-1)

只有一件接收到的加封檔案Ex(t)被用於公式(8-1)中。在一組4到4的波前解覆用運算的第二,第三,和第四個輸入的數據都是已知數據。從波前解覆用運算中解出的S(t)就是的嵌入的數碼訊息,應包括一句 “芝麻開門〞的英文短句,其4字的中文翻譯及發音。Only one received seal file Ex(t) is used in equation (8-1). The data of the second, third, and fourth inputs of the operation of a set of 4 to 4 wavefronts are known data. The embedded digital information that S(t) solves from the wavefront decoding operation should include a sentence of “Sinus opening English short sentence, its 4 words Chinese translation and pronunciation.

此外公式(7-2)中的O2,O3,和O4可基於所恢復的Ex(t)重新組構。重組後的O2,O3,以及O4可以和原來的數碼比較。其目的在於增強數碼的標識性。Further, O2, O3, and O4 in the formula (7-2) can be reconfigured based on the restored Ex(t). The reorganized O2, O3, and O4 can be compared to the original number. Its purpose is to enhance the identity of the digital.

實施例5中In the fifth embodiment

圖8和圖9描繪了用高階波前覆用/解覆用來做加封/解加封的運算。在此處的一組4到4波前覆用轉換的四串輸出中,有兩串是做作為加封數據集透過雲端010被發送到目的地的封后數碼串。Figures 8 and 9 depict the operation of applying/unwrapping with high order wavefront for unsealing/unwrapping. In this group of 4 to 4 wavefront-converted four-string outputs, two strings are used as a sealed data set to be sent to the destination via the cloud 010.

圖 8描述了使用高階波前覆用的技術,用於郵件數據加封的發送(Tx)經營理念。我們用一套4到4 波前覆用作為操作概念的例證。為加封/解加封操作概念的三段分組是與圖1中所示的那些相同;包括了(1) 預處理630或加封處理,(2)透過雲端010傳送,以及(3)後處理640或解加封處理。此圖示出了前兩段。Figure 8 depicts the transmission (Tx) business philosophy for mail data encapsulation using techniques that are applied with higher-order wavefronts. We use a set of 4 to 4 wavefronts as an illustration of the concept of operation. The three-segment grouping for the sealing/unsealing operation concept is the same as those shown in FIG. 1; includes (1) pre-processing 630 or encapsulation processing, (2) transmission through cloud 010, and (3) post-processing 640 or Unpacking process. This figure shows the first two paragraphs.

在預處理630中一套4到4 波前覆用的運作有四條輸入端分別連接到S(t),E10(t),E1(t)和E5(t),而只有兩條輸出端輸出一串Ex(t)和一串Ey(t)數據。其餘兩條輸出端接地。 S(t)包括一句“芝麻開門〞的英文短句和它的4字中文譯本及發音,並且是罩在透過雲端被交付給目的地的數碼訊息內。 E5(t) 是由所述的候選信封文檔180為所選出的數碼信封,作為第一輸出端輸出的Ex(t)數碼串和所述第三輸出端輸出的Ey(t)數碼串的其中一串,每串外形對人類感官而言基本都與E5(t)的外形相同。所述第二和第三輸入端接入的E10(t)和E1(t) 數碼串也是由所述的候選信封文檔180中所選的檔案。對發送方及接收方而言,候選信封文檔180中的檔案都是已知的。In the pre-processing 630, a set of 4 to 4 wavefronts is applied with four inputs connected to S(t), E10(t), E1(t) and E5(t), respectively, and only two outputs are output. A string of Ex(t) and a string of Ey(t) data. The other two outputs are grounded. S(t) consists of a slang open English sentence and its 4 word Chinese translation and pronunciation, and is covered in a digital message delivered to the destination through the cloud. E5(t) is a digital envelope selected by the candidate envelope document 180, and the Ex(t) digital string outputted as the first output terminal and the Ey(t) digital string outputted by the third output terminal. A string, each string shape is basically the same as the shape of E5(t) for human senses. The E10(t) and E1(t) digit strings accessed by the second and third inputs are also files selected by the candidate envelope document 180. The files in the candidate envelope document 180 are known to both the sender and the recipient.

當用一套4到4海大媽矩陣為波前覆用/解覆用的轉換,此處的數學推導是與那些在圖2中的相同。在預處理630中的一套4至4 波前覆用根據公式(7)可寫為︰(7-3)When using a set of 4 to 4 sea aunt matrices for wavefront overriding/unwrapping, the mathematical derivation here is the same as those in Figure 2. A set of 4 to 4 wavefronts in pre-processing 630 can be written as follows according to equation (7): (7-3)

第一和第三條輸出端所輸出的數碼串,O1和O3,分別被命名為Ex(t)和Ey (t) 的數碼串。圖8中的其他2條輸出端被接地。由於縮放因子am被設定為~10,所以,無論是Ex(t)和Ey(t)的外觀在分別透過雲端010被傳遞到目的地過程中與E5(t)的外觀對人類感官而言基本上是完全相同的。The digital strings output by the first and third outputs, O1 and O3, are named as digital strings of Ex(t) and Ey (t), respectively. The other two outputs in Figure 8 are grounded. Since the scaling factor am is set to ~10, both the appearance of Ex(t) and Ey(t) are transmitted to the destination through the cloud 010, respectively, and the appearance of E5(t) is fundamental to human senses. The above is exactly the same.

圖9是在目的地的解加封方框圖; 也是圖8的反轉處理圖。它描述了使用高階波前解覆用技術對封后數據串做解加封或稱開封運算的訊息數據接收(Rx) 經營理念。Figure 9 is a block diagram of the de-seal at the destination; also the reverse processing diagram of Figure 8. It describes the message data reception (Rx) business philosophy of using the high-order wavefront de-embedding technique to de-encapsulate or unpack the sealed data string.

波前覆用後的四串數碼數據中只有兩串透過雲端010發送到目的地,所需的通信信道的總帶寬可以應是S(t)信號本身的兩倍左右。當被適當選出地數碼信封E5經在預處理630中進一步優化而轉換成的兩串封后數碼串,每串封后數碼檔案所需通信信道的帶寬可以相應地是 S(t) 的本身頻寬一樣寬的通信帶寬。Only two of the four strings of digital data after the wavefront are transmitted to the destination through the cloud 010, and the total bandwidth of the required communication channel should be about twice that of the S(t) signal itself. When the properly selected digital envelope E5 is further optimized by the pre-processing 630 and converted into two strings of sealed digital strings, the bandwidth of the communication channel required for each string of digital files may be correspondingly the frequency of S(t). The same wide communication bandwidth.

在後處理640中用了一套4對4 波前解覆用運算。含有四條輸入端;分別接入 (1)Ex(t);接收到的第一串數碼串,(2)Ey(t);接收到的第二串數碼串,(3)E10(t);從候選信封文檔180中選出的一串已知數碼數據,和(4)E5(t);從候選信封文檔180中選出的一串已知數碼數據的一件數碼信封。根據公式(7-3);                  Ex(t) =am* E5(t)+ E1(t)+ E10(t)+ S(t)                    (7-4)              Ey(t) =am* E5(t)+ E1(t) - E10(t) - S(t)                    (7-5)       和   S(t)=[Ex(t) - Ey(t)] /2 - E10(t)                                 (9)A set of 4-pair 4-wavefront unwrapping operations is used in post-processing 640. Contains four inputs; respectively access (1) Ex(t); received first string of digits, (2) Ey(t); received second string of digits, (3) E10(t); A series of known digital data selected from the candidate envelope document 180, and (4) E5(t); a digital envelope of a string of known digital data selected from the candidate envelope document 180. According to the formula (7-3); Ex(t) = am* E5(t) + E1(t) + E10(t) + S(t) (7-4) Ey(t) = am* E5(t) + E1(t) - E10(t) - S(t) (7-5) and S(t)=[Ex(t) - Ey(t)] /2 - E10(t) (9)

在公式(9)中利用了接收到的兩串封后數碼串,Ex(t)和Ey(t)。此4至4 波前解覆用的第三條輸入為E10(t); 是一串已知的數據。第四條輸入為E5(t); 也是已知的數據集。在公式(9)中不需要E5(t)就可算出S(t)。但是,從四件波前覆用轉換後的數碼檔案中選出兩件作為兩串封后檔案數碼串會有六種不同的組合。這六種組合中都可利用已知的三組數據E10,E1和E5做恢復S(t)的重組運算,但許多組合在恢復S(t)的重組運算中需要多於一組的已知數據。The received two strings of sealed digital strings, Ex(t) and Ey(t), are utilized in equation (9). The third input for this 4 to 4 wavefront solution is E10(t); is a string of known data. The fourth input is E5(t); it is also a known data set. S(t) can be calculated without E5(t) in equation (9). However, there are six different combinations of two strings selected from the four wavefront-converted digital files as two strings of sealed files. The known three sets of data E10, E1 and E5 can be used to recover S(t) recombination operations in these six combinations, but many combinations require more than one set of known recombination operations to recover S(t). data.

從波前解覆用運算求出的S(t)應就是罩在數碼信封內的數碼訊息,並包括一句 “芝麻開門〞的英文短句,其4字的中文翻譯及發音。The S(t) obtained from the wavefront decoding operation should be the digital message enclosed in the digital envelope, and includes a sentence of “Sinus opening English short sentence, its 4 words Chinese translation and pronunciation.

此外根據公式(7-2),在目的地O2和O4可從運算所求出的S(t)再重新算出。其結果 再與原來數據比較。重算後的O2和O4可以用於增強的數據標識性。Further, according to the formula (7-2), the destinations O2 and O4 can be recalculated from the S(t) obtained by the calculation. The result is compared with the original data. The recalculated O2 and O4 can be used for enhanced data identification.

實施例6Example 6

圖10示出採用更高階的波前覆用技術,用於郵件數據加封發送(Tx)的經營理念。我們用一套4到4 波前覆用作為操作概念的。這套4到4波前覆用的四條輸出中有三條輸出作為封后數碼串透過雲端010被發送到目的地。Figure 10 shows the business philosophy of using a higher-order wavefront overlay technique for mail data seal transmission (Tx). We use a set of 4 to 4 wavefronts as an operational concept. Three out of the four outputs of the 4 to 4 wavefront are sent as the sealed digital string to the destination through the cloud 010.

這一套在預處理630中的4到4 波前覆用是有四條輸入端分別接入S(t),E10(t),E1(t)和E5(t)。其四條輸出端只有三條分別輸出Ex(t),Ey(t) 和Ez(t)。剩下的一條輸出被接地。在四條輸出中選出三條有4種可能的配置選擇。 S(t)是將要透過雲端交付給目的地的訊息數碼並且包括一句 “芝麻開門〞的英文短句,其4字的中文翻譯及發音。 E5(t)是從所述候選信封文檔180中所選出的數碼信封。另外對人類感官而言,在所述的第一輸出Ex(t),第二輸出Ey(t),和第三輸出Ez(t) 中,每串外觀特徵與E5(t)的那些外觀特徵基本上是相同的。在所述第二和第三輸入端接入的E10(t)和E1(t)的也是從所述候選數碼信封檔案中180所選出的檔案。對發送者和接收者而言這些選出的都是已知的數碼檔案。此圖用一套4到4海大媽矩陣做為波前覆用和解覆用數學推導是與那些在圖2中的相同。根據公式(7),在預處理630中的一套4至4 波前覆用運算為︰(7-6)This set of 4 to 4 wavefronts in pre-processing 630 is applied with four inputs connected to S(t), E10(t), E1(t) and E5(t). Only three of its four outputs output Ex(t), Ey(t) and Ez(t). The remaining output is grounded. There are 4 possible configuration options for selecting three out of the four outputs. S(t) is a message number that will be delivered to the destination through the cloud and includes an English short sentence with a sap open, with a 4-character Chinese translation and pronunciation. E5(t) is a digital envelope selected from the candidate envelope document 180. Further for human senses, in the first output Ex(t), the second output Ey(t), and the third output Ez(t), each appearance characteristic and those appearance features of E5(t) Basically the same. E10(t) and E1(t) accessed at the second and third inputs are also files selected from the candidate digital envelope archive 180. For the sender and receiver, these are all known digital files. This figure uses a set of 4 to 4 sea aunt matrices as wavefront overrides and solutions. The mathematical derivation is the same as those in Figure 2. According to equation (7), a set of 4 to 4 wavefront override operations in preprocessing 630 is: (7-6)

它的第一,第二,和第三輸出端,O1,O2,以及O3,被分別命名為Ex(t),Ey(t),和Ez(t)。在圖10中的第四輸出端被接地。Ex(t),Ey (t),和Ez(t)將分別透過雲端010被傳遞到目的地。縮放因子am被設定為~10的結果是使三串輸出封后數碼串中的任一串外觀特徵,無論是Ex(t),Ey(t),或Ez(t),在傳遞過程中對人體的器官而言基本上與E5(t)的外觀相同。Its first, second, and third outputs, O1, O2, and O3, are named Ex(t), Ey(t), and Ez(t), respectively. The fourth output in Figure 10 is grounded. Ex(t), Ey (t), and Ez(t) will be delivered to the destination through the cloud 010, respectively. The result of setting the scaling factor am to ~10 is to make any string of appearance features in the three-string output sealed digital string, whether Ex(t), Ey(t), or Ez(t), during the transfer. The organs of the human body are basically the same as the appearance of E5(t).

被當適當地選擇數碼信封E5在預處理630進一步優化後,三串封后數碼檔案, 每件所需信道帶寬分別與S(t)的本身信道帶寬一樣大。所以傳遞過程所需的通信信道帶寬相應地約是S(t)信號本身帶寬的3倍。額外的帶寬差異是由於處理開銷。When the digital envelope E5 is properly selected and further optimized in the pre-processing 630, the three-string digital file, each required channel bandwidth is as large as the S(t)'s own channel bandwidth. Therefore, the communication channel bandwidth required for the transfer process is correspondingly about three times the bandwidth of the S(t) signal itself. The extra bandwidth difference is due to processing overhead.

圖11是一幅在目的地的解加封運作框圖; 也是圖10的反轉處理圖。它描述了解加封運作接收(Rx)訊息數碼的經營理念。在目的地只需及時接收到透過雲端010三串波前覆用運作後的封后數碼中的兩串。此圖假定Ex(t)和Ey(t)就是在目的地所接收的兩串先到的封后數碼串。Figure 11 is a block diagram of the de-seal operation at the destination; also the reverse processing diagram of Figure 10. It describes the business philosophy of understanding the digital operation of the seal (Rx) message. In the destination, it is only necessary to receive the two strings in the sealed digital after the operation of the cloud 010 three-string wavefront. This figure assumes that Ex(t) and Ey(t) are the two strings of first-come, sealed digital strings received at the destination.

在後處理640中的一套4對4 波前解覆用運作。有四條輸入端分別接入四串數碼; (1)Ex(t);第一串接收到的封后數碼串,(2)Ey(t);第二串接收到的封后數碼串, (3)E10(t)是一件在候選信封文檔180已知數碼檔案,和(4)E5(t)是另一件在候選信封文檔180已知數碼檔案,也是一件已選出的數碼信封。根據公式(7-6);                  Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t)                     (7-8)                Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t)                     (7-9)                Ez(t)=am* E5(t)+ E1(t) - E10(t) - S(t)                     (7-10)   和          S(t)=[Ex(t) - Ey(t)] /2+ E1(t)                                   (10)A set of 4 to 4 wavefront solutions in post processing 640 operates. There are four input terminals respectively connected to four serial numbers; (1) Ex(t); the first string received digital string, (2) Ey(t); the second string received digital string, ( 3) E10(t) is a known digital archive in the Candidate Envelope Document 180, and (4) E5(t) is another known digital archive in the Candidate Envelope Document 180, which is also an optional digital envelope. According to the formula (7-6); Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t) (7-8) Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t) (7-9) Ez(t)=am* E5(t)+ E1(t) - E10(t) - S(t) (7-10 ) and S(t)=[Ex(t) - Ey(t)] /2+ E1(t) (10)

公式(10)含有兩件接收到的封后數碼檔案Ex(t)和Ey(t)。這套4至4 波前解覆用運算的第三輸入E1(t)是一件已知的數碼檔案。同樣它的第四輸入E5(t)也是已知的數據​​集。但在公式(10)求S(t)的運算中是不需要E5(t)的。Equation (10) contains two pieces of received digital archives Ex(t) and Ey(t). The third input E1(t) of the 4 to 4 wavefront cancellation operation is a known digital file. Also its fourth input E5(t) is also a known data set. However, E5(t) is not required in the operation of equation (10) for S(t).

從波前解覆用運算中 求出的S(t)應是在傳遞過程中罩在數碼信封中的訊息數碼,並包括一句 “芝麻開門〞的英文短句,其4字的中文翻譯及發音。The S(t) obtained from the wavefront decoding operation should be the message number enclosed in the digital envelope during the transmission process, and include a sentence of "Sesame opening English short sentence, its 4 words Chinese translation and pronunciation. .

此外根據公式(7-2),O3和O4可在目的利用新求出S(t)重新算出。重組後的O3和O4可與原數碼數據相比以用於增強數碼數據的標識性。Further, according to the formula (7-2), O3 and O4 can be newly calculated by using the new S(t) for the purpose. The reorganized O3 and O4 can be used to enhance the identification of digital data compared to the original digital data.

圖12是另一幅在目的地的解加封運作框圖; 也是圖10的反轉處理圖。它描述了解加封運作接收(Rx)訊息數碼的經營理念。在目的地只需及時接收到透過雲端010三串波前覆用運作後的封后數碼中的兩串。此圖假定Ez(t)和Ey(t)就是在目的地所接收的兩串先到的封后數碼串。Figure 12 is a block diagram of another de-seal operation at the destination; also a reverse processing diagram of Figure 10. It describes the business philosophy of understanding the digital operation of the seal (Rx) message. In the destination, it is only necessary to receive the two strings in the sealed digital after the operation of the cloud 010 three-string wavefront. This figure assumes that Ez(t) and Ey(t) are the two strings of first-come, sealed digital strings received at the destination.

在後處理640中的一套4對4 波前解覆用運算有四條輸入端; 分別接入四串數碼檔案;(1)Ex(t)是第一件接收到的封后數碼檔案,(2) Ey(t)是的第二件接收到的封后數碼檔案,(3)E10(t)是從已知的候選信封文檔180選出,和(4) E5(t) 也是從候選信封文檔180選出的一件已知的數字數據, 也是所選的數碼信封。根據公式(7-6);                  Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t)                     (7-11)                Ez(t)=am* E5(t)+ E1(t) - E10(t) - S(t)                     (7-12)   和          S(t)=am* E5(t) - [Ey(t)+ Ez(t)] /2                            (11)In the post-processing 640, a set of 4 pairs of 4 wavefront decoding operations has four inputs; respectively, four series of digital files are accessed; (1) Ex(t) is the first received digital file, ( 2) Ey(t) is the second received digital archive, (3) E10(t) is selected from the known candidate envelope document 180, and (4) E5(t) is also the candidate envelope document One of the known digital data selected by 180 is also the selected digital envelope. According to the formula (7-6); Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t) (7-11) Ez(t)=am* E5(t) + E1(t) - E10(t) - S(t) (7-12) and S(t)=am* E5(t) - [Ey(t)+ Ez(t)] /2 (11)

在公式(11)中使用了兩件接收到的封后檔案Ey(t)和Ez(t)。此套4至4 波前解覆用運算的第三條輸入為E1(t)的; 是一件已知的數碼數據。其第四輸條入E5(t)的;也是已知的數碼數據。但利用公式(11)來求S(t)的恢復運算時不需要E1(t)的。從波前解覆用運算中新求出的S(t)應是在傳輸過程中罩在交付數碼信封內的數碼訊息,應包括“芝麻開門〞的英文短句和它的四字中文翻譯本和發音。此外O1和O4,也可以根據公式(7-6)用新求出S(t)新重算出,再與O1和O4的原數碼數據比較用於增強數碼數據的標識性。Two pieces of received archived files Ey(t) and Ez(t) are used in equation (11). The third input of this set of 4 to 4 wavefront decompression operations is E1(t); it is a known digital data. Its fourth line is entered into E5(t); it is also known digital data. However, E1(t) is not required for the recovery operation of S(t) using equation (11). The new S(t) obtained from the wavefront decoding operation should be the digital message covered in the delivery digital envelope during the transmission process. It should include the English short sentence of the sesame opening and its four-character Chinese translation. And pronunciation. In addition, O1 and O4 can also be calculated from the new S(t) new weight according to formula (7-6), and then compared with the original digital data of O1 and O4 to enhance the identification of digital data.

圖13是另一幅在目的地的解加封運作框圖; 也是圖10的反轉處理圖解。它描繪了解加封運作訊息的數據,在透過雲端010把三件波前覆用處理後的封后數碼檔案Ex(t),Ey(t),和Ez(t) 及時的送到目的的接收(Rx)經營理念。Figure 13 is a block diagram of another de-seal operation at the destination; also an inverse processing diagram of Figure 10. It depicts the data of the operation information of the seal, and sends the three post-processing digital archives Ex(t), Ey(t), and Ez(t) to the destination for reception in time through the cloud 010. Rx) business philosophy.

在後處理640中的一套4對4 波前解覆用運算有四條輸入端; 分別接入四件數碼檔案;(1)Ex(t)是第一件接收到的封后數碼檔案,(2)Ey(t)的是第二件接收到的封后數碼檔案,(3)E1(t)是從已知的候選信封文檔180選出的一件檔案,和(4)Ez(t)第三件接收到的封后數碼檔案。 根據公式(7-6);                Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t)                     (7-13)                Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t)                     (7-14)                Ez(t)=am* E5(t)+ E1(t) - E10(t) - S(t)                     (7-15)         和   S(t)=am* E5(t) - [Ey(t)+ Ez(t)] /2                            (12-1)         或   S(t)=[Ex(t)-Ey(t)] / 2 - E1(t)                                    (12-2)         或   S(t)=[Ex(t)-Ez(t)] /2 - E10(t)                                   (12-3)In the post-processing 640, a set of 4 pairs of 4 wavefront decoding operations has four inputs; respectively, four digital files are accessed; (1) Ex(t) is the first received digital file, ( 2) Ey(t) is the second received digital archive, (3) E1(t) is a file selected from the known candidate envelope document 180, and (4) Ez(t) Three received digital archives. According to the formula (7-6); Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t) (7-13) Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t) (7-14) Ez(t)=am* E5(t)+ E1(t) - E10(t) - S(t) (7-15 ) and S(t)=am* E5(t) - [Ey(t)+ Ez(t)] /2 (12-1) or S(t)=[Ex(t)-Ey(t)] / 2 - E1(t) (12-2) or S(t)=[Ex(t)-Ez(t)] /2 - E10(t) (12-3)

對三件接收到的封后數碼檔案,Ex(t),Ey(t)和Ez(t)而言,在利用公式(12)做數碼郵件S(t) 恢復的運算中會使用其中的兩件。公式(12-1),(12-2)和(12-3)分別描繪三種選項來做數碼郵件S(t) 的恢復運算。它們都需要所劃定的第三件輸入到此套4到4 波前解覆用的數碼檔案。根據公式(12-1)的恢復處理所要求的第三件檔案是原始數碼信封E5(t)。類似地,根據公式(12-2)和(12-3)與所述第三檔案分別是E1(t)和E10(t)的數碼檔案。For the three received digital archives, Ex(t), Ey(t) and Ez(t), two of them will be used in the calculation of digital mail S(t) recovery using equation (12). Pieces. Equations (12-1), (12-2), and (12-3) respectively depict three options for the recovery operation of the digital mail S(t). They all require a third piece of data to be entered into this set of 4 to 4 wavefront solutions. The third file required for recovery processing according to equation (12-1) is the original digital envelope E5(t). Similarly, according to formulas (12-2) and (12-3) and the third file are digital files of E1(t) and E10(t), respectively.

利用公式(12)有三組可能恢復重組S(t) 運算的靈活性所組的接收器可利用接收三件數碼中任何可能先到兩件來運算,Ex(t),Ey(t)和Ez(t)。也可只利用這三件波前覆用後的數碼檔案中被送到目的地前兩件數碼和丟棄從源頭髮送來的最後一件(第三件)。 這類雲端傳輸技術來提供及時音樂或視頻短片的服務,應可增強型數據流的速度並提供更好的數據流在雲端的生存性和可靠性。Using Equation (12), there are three sets of possibilities for recovering the flexibility of the recombination S(t) operation. The receivers of the group can use any of the three pieces of digital data that can be used first to two operations, Ex(t), Ey(t) and Ez. (t). It is also possible to use only the first two pieces of the digital file that have been sent to the destination before the three wavefronts are discarded and to discard the last piece (third piece) sent from the source. This type of cloud-based transmission technology provides timely music or video clips that should enhance the speed of data streams and provide better data stream survivability and reliability in the cloud.

在其他應用中,上述的多種修復運算方法,可用於區分多播模式或廣播模式服務的偏好的。在上述不同的實例中對於那些沒有接入E1和E10 的客戶; 若只透過雲端010同時只發送Ey和Ez給他們, 這項服務是完全無效而被否定的。同樣的,若透過雲端010再加送Ex(t) 為這群客戶做視頻流服務但控制Ex(t) 的數碼流速,以較慢的速度傳送。譬如將前兩串數碼流用三分之一的機率處於正常率透過雲端010送到目的地。 其結果在客戶端恢復視頻的過程中。當Ex(t)的傳遞流率被顯著降低或被延遲在接收到的對應總流量的三分之二流量是在正常流率的33%。In other applications, the various repair operations described above can be used to distinguish between preferences for multicast mode or broadcast mode services. In the above different examples, for those customers who do not have access to E1 and E10; if only Ey and Ez are only sent to them through the cloud 010, the service is completely invalid and denied. Similarly, if you send Ex(t) through the cloud 010 to do video streaming services for this group of customers, but control the digital flow rate of Ex(t), it will transmit at a slower speed. For example, the first two strings of digital streams are sent to the destination through the cloud 010 at a normal rate of one-third. The result is in the process of restoring the video on the client side. When the transfer rate of Ex(t) is significantly reduced or delayed, the two-thirds of the traffic corresponding to the total flow received is 33% of the normal flow rate.

圖14是另一幅在目的地的解加封運作框圖; 也是圖10的反轉處理圖。這套方案是選擇利用3件波前覆用後數碼數據Ex(t),Ey(t),與Ew(t),透過雲端010發送到目的地。它描繪了一組透過雲010的三件覆用運作後的數碼數據,在目的地透過解加封運作的數碼訊息接收(Rx)的經營理念。在目的地及時接收到三件波前覆用後的數碼數據是Ex(t),Ey(t)與Ew(t)。Figure 14 is a block diagram of another de-seal operation at the destination; also the reverse processing diagram of Figure 10. This solution is to choose to use 3 pieces of wavefront overlay digital data Ex(t), Ey(t), and Ew(t) to send to the destination through cloud 010. It depicts a set of three-in-one digital data through cloud 010, and the digital message reception (Rx) operation at the destination through de-sealing. The digital data that is received in the destination in time for the three wavefronts is Ex(t), Ey(t) and Ew(t).

在後處理640中的一套4對4 波前解覆用運算有四條輸入端分別接入四串數碼數據; (1)Ex(t)是及時接收到的第一串數碼數據,(2)Ey(t) 是及時接收到的第二串數碼數據,(3)E1(t)是從候選信封文檔180中選出的一件已知數碼檔案,和(4)Ew(t)是及時接收到的第三串數碼數據。 根據公式(7-6);                Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t)                     (7-16)                Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t)                     (7-17)                Ew(t)=am* E5(t)-E1(t) - E10(t)+ S(t)                      (7-18)                 和   S(t)= E10(t)+Ey(t)-Ew(t)] /2                             (12-4)              或   S(t)=[Ex(t) - Ey(t)] / 2 - E1(t)                            (12-5)              或   S(t)=[Ex(t)+ Ew(t)] /2    amE5(t)                       (12-6)In the post-processing 640, a set of 4 pairs of 4 wavefront decoding operations has four inputs for respectively accessing four strings of digital data; (1) Ex(t) is the first string of digital data received in time, (2) Ey(t) is the second string of digital data received in time, (3) E1(t) is a known digital file selected from the candidate envelope document 180, and (4) Ew(t) is received in time. The third string of digital data. According to the formula (7-6); Ex(t)=am* E5(t)+ E1(t)+ E10(t)+ S(t) (7-16) Ey(t)=am* E5(t) - E1(t)+ E10(t) - S(t) (7-17) Ew(t)=am* E5(t)-E1(t) - E10(t)+ S(t) (7-18 ) and S(t)= E10(t)+Ey(t)-Ew(t)] /2 (12-4) or S(t)=[Ex(t) - Ey(t)] / 2 - E1 (t) (12-5) or S(t)=[Ex(t)+ Ew(t)] /2 amE5(t) (12-6)

在公式(12) 的每條公式中都用到三串接收封后數碼檔案,Ex(t),Ey(t),和Ew(t) 中的兩串。這裡有三選項分別利用公式(12-4),(12-5),和(12-6)來做所劃定數碼郵件S(t)的復原處理運算。類似於圖13的框圖,它們都需要一件接到此套4到4 波前解覆用運作第三輸入端的數碼檔案。根據公式(12-4)的復原處理,所需要接入第三輸入端的檔案是原始數碼檔案E10(t)。同樣地,根據公式(12-5)和(12-6) 復原處理與所述接入第三輸入端的檔案分別是E1(t)和那的E5(t)的數字檔案。In each of the formulas of equation (12), three strings of received digital files, Ex(t), Ey(t), and Ew(t) are used. Here, there are three options for using the formulas (12-4), (12-5), and (12-6) to perform the restoration processing of the delimited digital mail S(t). Similar to the block diagram of Figure 13, they all require a digital archive that is connected to the fourth input of the 4 to 4 wavefront solution. According to the restoration process of the formula (12-4), the file to be accessed to the third input terminal is the original digital file E10(t). Similarly, the files corresponding to the equations (12-5) and (12-6) are restored to the digital file of E1(t) and E5(t), respectively.

利用公式(12)有三組可能恢復重組S(t) 運算的靈活性所組的接收器可利用接收三件數碼中任何可能先到兩件來運算,Ex(t),Ey(t)和Ew(t)。也可只利用這三件波前覆用後的數碼檔案中被送到目的地前兩件數碼和丟棄從源頭髮送來的最後一件(第三件)。 這類雲端傳輸技術來提供及時音樂或視頻短片的服務,應可增強型數據流的速度並提供更好的數據流在雲端的生存性和可靠性。Using Equation (12), there are three sets of possibilities for recovering the flexibility of the recombination S(t) operation. The receivers of the group can use any of the three pieces of digital to receive the first two operations, Ex(t), Ey(t) and Ew. (t). It is also possible to use only the first two pieces of the digital file that have been sent to the destination before the three wavefronts are discarded and to discard the last piece (third piece) sent from the source. This type of cloud-based transmission technology provides timely music or video clips that should enhance the speed of data streams and provide better data stream survivability and reliability in the cloud.

實施例7中In the seventh embodiment

圖15描繪透過使用兩套波前覆用設定的加封順序對數碼訊息郵件做雙加封發送的經營理念。它示出了圖 1的三段處理中的前兩段。圖 1的三段處理包括︰(1)預處理130或加封處理,(2)透過雲端010傳送,和(3)後處理140或解加封處理。Figure 15 depicts the business philosophy of double-sending digital message mail by using two sets of wavefront overrides. It shows the first two of the three-stage process of Figure 1. The three-stage processing of FIG. 1 includes: (1) pre-processing 130 or encapsulation processing, (2) transmission through cloud 010, and (3) post-processing 140 or de-encapsulation processing.

圖15描繪的雙加封處理含有在串聯的兩套加封處理。內層數碼加封和外層數碼加封的運作分別與圖6中的加封運作及圖1中的加封運作是相同的。第一預處理630中的四條輸入端分別接入4串數碼數據檔案,S(t),E10(t),E1(t)和E4(t)。它的4條輸出端的唯一輸出被分發為輸出一件w(t)的數碼檔案。其他3件輸出,x(t),y(t),和z(t),都被接地。 S(t)是透過雲端交付到目的地的數碼訊息,應包括一句“芝麻開門〞的英文短句,及中文翻譯和發音。 E4(t)是一件從候選信封文檔180選定的內層數碼信封。對人體感官而言,第一件輸出w(t)的外型特點與E4(t)的外型基本上完全相同。The double seal process depicted in Figure 15 contains two sets of seal processes in series. The operation of the inner digital seal and the outer digital seal is the same as the seal operation in Fig. 6 and the seal operation in Fig. 1, respectively. The four inputs in the first pre-processing 630 respectively access 4 strings of digital data files, S(t), E10(t), E1(t) and E4(t). The unique output of its four outputs is distributed to output a digital file of w(t). The other three outputs, x(t), y(t), and z(t), are all grounded. S(t) is a digital message delivered to the destination through the cloud. It should include an English phrase that opens the door and a Chinese translation and pronunciation. E4(t) is an inner digital envelope selected from the candidate envelope document 180. For human senses, the appearance of the first output w(t) is essentially identical to that of E4(t).

第二套的預處理130有兩條輸入端分別接入w(t)和E5(t)數碼串, 而它的第一輸出端被指定為輸出Es(t) 數碼串的。它的第二輸出端被接地。 E5(t) 數碼串是從候選信封文檔180所選出的外層數碼信封。對人體感官而言,第一件輸出Es(t)的外型特點與E5(t)的外型基本上完全相同。The second set of pre-processing 130 has two inputs connected to the w(t) and E5(t) string, respectively, and its first output is designated as the output Es(t) string. Its second output is grounded. The E5(t) digital string is an outer digital envelope selected from the candidate envelope document 180. For human senses, the appearance of the first output Es(t) is essentially identical to that of E5(t).

只有一件波前覆用運作後的數碼檔案Es(t)會透過雲端010被發送到目的地。Es(t)的外觀並沒有一句“芝麻開門〞的英文短句或它的中文翻譯。當E4(t)或E5(t)是適當選出時。用於及時輸送Es(t)的所需頻帶帶寬與透過雲端發送S(t) 所需帶寬應非常接近相同。Only one wave of the digital file Es(t) after the operation is sent to the destination via the cloud 010. The appearance of Es(t) does not have a sentence saying "the essay opens the English phrase or its Chinese translation. When E4(t) or E5(t) is properly selected. The required bandwidth for transmitting Es(t) in time should be very close to the bandwidth required to transmit S(t) through the cloud.

在其它實施例中,在加封檔案的圖像為了各種目的可能先被預處理過,例如為了降低單個像素的動態範圍,或簡單地為波前覆用之前增強身分驗証和鑑定。許多被預處理過的數碼檔案可預先存儲在候選數碼信封檔案中作為可選的候選數碼檔案按。當然,這些額外的預處理也可以被當作為第一套的預處理630和/或第二套的預處理130的一部分。In other embodiments, the image of the sealed archive may have been pre-processed for various purposes, such as to reduce the dynamic range of a single pixel, or simply enhance identity verification and authentication prior to wavefront overwriting. Many pre-processed digital files can be pre-stored in the candidate digital envelope file as an optional candidate digital file. Of course, these additional pre-processings can also be taken as part of the first set of pre-processing 630 and/or the second set of pre-processing 130.

圖16描述了使用波前解覆用方法去對雙加封數碼訊息做解加封的接收(Rx)經營理念。串聯的兩套解加封處理運作中,第一套的後處理140是來打開外層數碼信封,如圖1所示的解加封處理運作相同。它有兩條輸入端分別接入Es(t)和E5(t)的數碼檔案。 Es(t)是在目的地的接收器所期望接收到的封后數碼檔案,含有罩在其中的數碼訊息郵件。應大致和在圖15中所述第二套的預處理130的唯一輸出的數碼檔案相同。此外對人類感官而言Es(t) 外型特徵應與那些E5(t)的外型特徵基本上完全相同。 E5(t) 是一件 從候選信封文檔180中選出的外層數碼信封。對發送方和接收方而言候選信封文檔180中的數碼檔案都是已知的。Figure 16 depicts the reception (Rx) business philosophy of using a wavefront solution to de-encapsulate a double-encapsulated digital message. In the two sets of de-seal processing operations in series, the first set of post-processing 140 is to open the outer digital envelope, and the unseal processing as shown in FIG. 1 operates the same. It has two input ports for accessing Es(t) and E5(t) digital files. Es(t) is the sealed digital file that the receiver at the destination expects to receive, containing the digital message mail draped in it. It should be substantially the same as the uniquely output digital file of the second set of pre-processing 130 described in FIG. In addition, the Es(t) appearance characteristics of human senses should be substantially identical to those of E5(t). E5(t) is an outer digital envelope selected from the candidate envelope document 180. The digital files in the candidate envelope document 180 are known to both the sender and the recipient.

同樣,後處理140也有兩條輸出端。從後處理140第一輸出端輸出的一串數碼檔案w(t), 其 外觀對人體感官而言與E4(t)的外觀基本相同。它的第二輸出端被接地。Similarly, post processing 140 also has two outputs. A string of digital files w(t) outputted from the first output of post-processing 140 has an appearance that is substantially identical to the appearance of E4(t) for human senses. Its second output is grounded.

第二套的後處理640有四條輸入端,分別連接到四串數碼檔案w(t),E10(t),E1(t)和E4(t)。 E4(t)是所選出的內層加封的數碼信封也是從候選信封文檔180中選出的。E10(t)和E1(t) 也是從候選信封文檔180中選出的兩件數碼檔案。第二套的後處理640的輸出端,除了第一條是指定為輸出S(t)之外,其餘的都被接地。第一輸出的S(t)就是復原的數碼訊息。The second set of post-processing 640 has four inputs connected to four strings of digital files w(t), E10(t), E1(t) and E4(t). E4(t) is the selected inner layer sealed digital envelope that is also selected from the candidate envelope document 180. E10(t) and E1(t) are also two digital files selected from the candidate envelope document 180. The output of the second set of post-processing 640 is grounded except that the first strip is designated as output S(t). The first output of S(t) is the restored digital message.

可以想到透過多套在源頭的M-到-M 波前覆用和多套的在後處理的M-到-M 波前解覆用,來延生如圖15和圖16所示的雙加封/解加封運作至多層加封/解加封運作,其中M是一個大於或等於2整數。It is conceivable to extend the double-sealing shown in Figures 15 and 16 through multiple sets of M-to-M wavefront coatings at the source and multiple sets of post-processing M-to-M wavefront solutions. De-seal operation to multi-layer sealing/unsealing operation, where M is an integer greater than or equal to 2.

實施例8Example 8

數碼加封及解加封可以用於數字權利管理(DRM)的工具。我們可用圖1來說明應用在發行一部新電影的一套DRM架構。將發行的原版電影是在母版本。我們將使用數碼加封技術在不同的子版本電影(拷貝)中隱藏地嵌入各種不同獨特的區別數碼檔案。在圖中所示的加封技術可利用如圖1,圖4,或圖6所示的數碼加封處理。每一子版新電影的拷和母版電影本基本上將具有相同的外觀和幾乎完全相同的視覺及聽覺電影功能。Digital sealing and unsealing can be used for digital rights management (DRM) tools. We can use Figure 1 to illustrate a set of DRM architectures for a new movie. The original movie that will be released is in the parent version. We will use digital sealing technology to hide and embed various unique and distinctive digital files in different sub-version movies (copy). The encapsulation technique shown in the figure can be processed by digital encapsulation as shown in FIG. 1, FIG. 4, or FIG. The copy and master movies of each new version of the film will basically have the same look and almost identical visual and auditory film functions.

當盜版電影本被發現,無論是透過分銷的壞管道洩漏產生的,或在商業電影院透過隱藏的錄影機所記錄的新影片,我們都可利用盜版及母版電影同時透過如圖1,圖5, 或圖7的解加封處理器來恢復重建一本隱藏嵌入在盜版電影本中的獨特區別數碼檔案。這些獨特的區別檔案將可識別出此盜版版本是源於何版的子版本。When pirated movies are found, whether they are leaked through the distribution of bad pipelines, or new movies recorded in commercial cinemas through hidden video recorders, we can use pirated and master movies simultaneously through Figure 1 and Figure 5. , or the unwrapped processor of Figure 7, to restore a uniquely differentiated digital file that is hidden in a pirated movie. These unique differences files will identify the subversions from which version of the pirated version.

在圖1中用於預處理130輸入端的Em(t) 代表原始的母版影片, Idx(t) 代表隱密嵌入在某子版影片的某獨特標識檔案 。預處理130一組4到4 波前覆用的第一輸出被配置成為子版電影拷貝Echx(t),其視頻和音頻輸出基本上將具有與母版電影Em(t)幾乎完全相同的視覺及聽覺電影功能。此波前覆用器剩下的兩條輸入端和三條輸出端被接地。Em(t) for the pre-processing 130 input in Figure 1 represents the original master video, and Idx(t) represents a unique identification file that is implicitly embedded in a sub-film. The first output of the pre-processing 130 set of 4 to 4 wavefronts is configured as a sub-film copy Echx(t) whose video and audio output will substantially have exactly the same vision as the master movie Em(t). And auditory movie features. The remaining two inputs and three outputs of this wavefront connector are grounded.

原母版電影本Em(t) 將不會公開發行。它們可以存儲在庫中或雲儲存中。子版電影將透過分佈的分銷管道公開發行。每一子版電影基本上都具有與母版電影本完全相同的畫面及音頻質量。但是每一子版電影本都透過數碼加封過程被隱密地嵌入唯一可識別的獨特標識檔案。母版電影功能變成為唯一的數碼信封。隱密嵌入標識訊息或獨特標識檔案都是子版電影本的一部分。隱密嵌入標識訊息並不是利用有形水印和不可見的無形水印的技術。The original master movie Em(t) will not be released publicly. They can be stored in a library or in a cloud storage. Sub-versions will be publicly distributed through distributed distribution channels. Each sub-page movie basically has the same picture and audio quality as the master movie. However, each sub-page of the film is implicitly embedded in the uniquely identifiable unique logo file through the digital seal process. The master movie feature becomes the only digital envelope. Hidden embedded logo messages or unique logo files are all part of a sub-page book. The implicit embedding of the identification message is not a technique that utilizes a tangible watermark and an invisible invisible watermark.

通常,一本子版電影,其中包括經由一組M-到-M 波前覆用處理而生成的覆用後檔案, 此處 M ( 2。一組M-到-M波前覆用處理器有M條相對的方程式。選定的子版電影本只能是對應M條方程式中的一條。若與某本子版電影相關聯的人員想對所選的子版本的電影做更多的拷貝和再分佈發行而想改變嵌入標識檔案時,他或她必須能夠有此波前覆用處理器其它M-1 條輸入數碼檔案。這些M-1輸入可以用做額外的探測,更多的隱私和增強認証, 或是其他目的。圖1所示是對於M= 2的數碼加封過程。Typically, a sub-version of a film, including a post-file created via a set of M-to-M wavefront overrides, where M (2. A set of M-to-M wavefront processors) M relative equations. The selected sub-version movie can only be one of the corresponding M equations. If a person associated with a sub-version movie wants to make more copies and redistribute the selected sub-version movies. When you want to change the embedded logo file, he or she must be able to use this wave to overwrite the processor with other M-1 input digital files. These M-1 inputs can be used for additional detection, more privacy and enhanced authentication. , or for other purposes. Figure 1 shows the digital sealing process for M = 2.

當某一子版電影的盜版拷貝在市場被捕獲或在分銷網路上被截獲,其子版電影的源頭可以透過如圖1所示波前解覆用處理而恢復重建的識別標識或獨特標識檔案而查出。圖1多路輸入的波前解覆用處理器包括至少兩條輸入檔案; 第一條是所查獲的盜版電影Echx(t),第二條是原始母版電影Em(t)。When a pirated copy of a sub-version is captured in the market or intercepted on the distribution network, the source of the sub-film can be restored to the reconstructed identification or unique identification file through the wavefront decoding process shown in Figure 1. And find out. The multi-input wavefront decoding processor of FIG. 1 includes at least two input files; the first is the seized pirated movie Echx(t), and the second is the original master movie Em(t).

我們在DRM應用中使用電影影片做數碼加封/數碼解加封技術的例子。相同的數碼加封/數碼解加封的技術原則也可使用於聲音或其它音頻數碼,透過雲或其他公共IP網路提供的應用中。We use movie films in DRM applications as examples of digital sealing/digital unsealing techniques. The same digital sealing/digital unsealing technology can also be used in applications such as voice or other audio digital, via cloud or other public IP networks.

另外,我們也可用圖17a說明應用在發行一部新電影的另一DRM架構。將發行的原版電影是在母版本。我們將使用數碼加封技術在不同的子版本電影(拷貝)中隱藏地嵌入各種不同獨特的區別數碼檔案。在圖中所示的加封技術可利用如圖1,圖4,或圖6所示的數碼加封處理。每一子版新電影的拷和母版電影本基本上將具有相同的外觀和幾乎完全相同的電影功能。我們選擇了圖6中的預處理630做為這裡的數碼加封處理器。In addition, we can also illustrate another DRM architecture applied to the release of a new movie using Figure 17a. The original movie that will be released is in the parent version. We will use digital sealing technology to hide and embed various unique and distinctive digital files in different sub-version movies (copy). The encapsulation technique shown in the figure can be processed by digital encapsulation as shown in FIG. 1, FIG. 4, or FIG. The copy and master moviebooks for each new version of the new movie will basically have the same look and almost identical movie functionality. We chose the pre-processing 630 in Figure 6 as the digital encapsulation processor here.

當盜版電影本被發現,無論是透過損壞的分銷管道洩漏產生的,或在商業電影院透過隱藏的錄影機所記錄的新電影片,我們都可利用盜版及母版電影同時透過如圖17b的解加封處理器來恢復重建一本隱藏嵌入在盜版電影本中的獨特區別數碼檔案。這些獨特的區別檔案將可識別出此盜版版本是源於何版的子版本。When pirated movies are found, whether they are leaked through a damaged distribution channel, or new movies recorded in a commercial video theater through a hidden video recorder, we can use pirated and master movies simultaneously through the solution in Figure 17b. The processor is sealed to restore a uniquely differentiated digital file that is hidden in the pirated movie. These unique differences files will identify the subversions from which version of the pirated version.

在圖17A中用於預處理630輸入端的Em(t) 代表原始的母版影片, Idx(t) 代表隱密嵌入在某子版影片的某獨特標識檔案。一組4到4 波前覆用的預處理630的第一輸出被配置成為子版電影拷貝Echx(t),其視頻和音頻輸出基本上將具有與母版電影Em(t)幾乎完全相同的電影功能。此波前覆用器剩下的兩條輸入端和三條輸出端被接地。Em(t) for the pre-processing 630 input in Figure 17A represents the original master video, and Idx(t) represents a unique identification file that is implicitly embedded in a sub-film. The first output of a set of 4 to 4 wavefront pre-processed 630 is configured as a sub-film copy Echx(t) whose video and audio output will be substantially identical to the master movie Em(t). Movie function. The remaining two inputs and three outputs of this wavefront connector are grounded.

原母版電影本Em(t) 將不會公開發行。它們可以存儲在庫中或雲儲存中。子版電影將透過分佈的分銷管道公開發行。每一子版電影基本上都具有與母版電影本完全相同的畫面及音頻質量。但是每一子版電影本都透過數碼加封過程被隱密地嵌入唯一可識別的獨特標識檔案。母版電影功能變成為唯一的數碼信封。隱密嵌入標識訊息或獨特標識檔案都是子版電影本的一部分。隱密嵌入標識訊息並不是利用有形水印和不可見的無形水印的技術。The original master movie Em(t) will not be released publicly. They can be stored in a library or in a cloud storage. Sub-versions will be publicly distributed through distributed distribution channels. Each sub-page movie basically has the same picture and audio quality as the master movie. However, each sub-page of the film is implicitly embedded in the uniquely identifiable unique logo file through the digital seal process. The master movie feature becomes the only digital envelope. Hidden embedded logo messages or unique logo files are all part of a sub-page book. The implicit embedding of the identification message is not a technique that utilizes a tangible watermark and an invisible invisible watermark.

通常,一本子版電影,其中包括經由一組M-到-M 波前覆用處理而生成的覆用後檔案。一組M-到-M波前覆用處理器有M條相對的方程式。選定的子版電影本只能是對應M條方程式中的一條。若與某本子版電影相關聯的人員想對所選的子版本的電影做更多的拷貝和再分佈發行而想改變嵌入標識檔案時,他或她必須能夠有此波前覆用處理器其它M-1 條輸入數碼檔案。這些M-1輸入可以用做額外的探測,更多的隱私和增強認証, 或是其他目的。圖1所示是對於M= 2的數碼加封過程,圖17a所示是對於M= 4時的另一種數碼加封過程。Typically, a sub-version of a movie includes an overwritten file generated via a set of M-to-M wavefront overrides. A set of M-to-M wavefront overlay processors have M relative equations. The selected sub-version movie can only be one of the corresponding M equations. If a person associated with a sub-version movie wants to make more copies and redistribute the selected sub-version of the movie and wants to change the embedded identification file, he or she must be able to have this wavefront override processor. M-1 enters a digital file. These M-1 inputs can be used for additional probing, more privacy and enhanced authentication, or for other purposes. Figure 1 shows the digital sealing process for M = 2, and Figure 17a shows another digital sealing process for M = 4.

當某一子版電影的盜版拷貝在市場被捕獲或在分銷網路上被截獲,其子版電影的源頭可以透過如圖1所示波前解覆用處理而恢復重建的識別標識或獨特標識檔案而查出。 圖17B在後處理640中波前解覆用處理器的多路輸入包括至少兩條輸入檔案; 第一條是所查獲的盜版電影Echx(t), 第二條是原始母版電影Em(t)。When a pirated copy of a sub-version is captured in the market or intercepted on the distribution network, the source of the sub-film can be restored to the reconstructed identification or unique identification file through the wavefront decoding process shown in Figure 1. And find out. Figure 17B. In the post-processing 640, the multi-input of the wavefront decoding processor includes at least two input files; the first is the seized pirated movie Echx(t), and the second is the original master movie Em(t). ).

對於多層分佈,類似的概念可以從子版電影本擴展到孫版電影本。電影分銷商的每一層都會有自己的工具來跟蹤在各自分銷網路的洩漏口。For multi-layer distributions, similar concepts can be extended from sub-films to grandchildren. Each layer of the film distributor has its own tools to track leaks in their respective distribution networks.

在其它實施方案中,預處理630或數碼加封處理的其他兩個輸入可不接地而用於更多認証或其他隱私的附加功能上。In other embodiments, the pre-processing 630 or the other two inputs of the digital seal process may be ungrounded for additional functionality for additional authentication or other privacy.

我們在DRM應用中使用電影影片做數碼加封/數碼解加封技術的例子。相同的數碼加封/數碼解加封的技術原則也可使用於聲音或其它音頻數碼,透過雲或其他公共IP網路提供的應用中。We use movie films in DRM applications as examples of digital sealing/digital unsealing techniques. The same digital sealing/digital unsealing technology can also be used in applications such as voice or other audio digital, via cloud or other public IP networks.

實施例9Example 9

數碼加封及解加封可以在重新廣播中給用戶隱密地提供附加訊息。我們可以再次用圖17A說明利用重新廣播給用戶隱密地提供附加訊息的架構1710。   最初的廣播Em(t),   作為一個例子,是一段30分鐘的國內母版新聞1800。我們將使用數碼加封技術在子版新聞2000廣播本Echx(t)中隱密地嵌入第二段特別報導Idx(t)。 如圖17A中所示在預處理630中數碼加封處理的結果使其輸出中的一本子版新聞廣播Echx(t) 與原始本的母版新聞廣播Em(t)將具有相同視頻及音頻的外觀功能。Digital seals and de-seals can provide users with additional information in a re-broadcast. We can again illustrate, with Figure 17A, an architecture 1710 that uses re-broadcast to provide users with additional information. The original broadcast Em(t), as an example, is a 30-minute domestic master news 1800. We will use the digital seal technology to implicitly embed the second special report Idx(t) in the sub-news 2000 broadcast Echx(t). As a result of the digital sealing process in the pre-processing 630 as shown in FIG. 17A, a sub-page news broadcast Echx(t) in the output thereof and the original master news broadcast Em(t) will have the same video and audio appearance. Features.

在用戶接收機1790,只有重複廣播消息Echx(t)與原始母版廣播檔案Em(t) 如圖17B所示同時透過在後處理640中相應的解加封處理器才能把第二段隱密特別報導Idx(t)重組恢復出來。 用戶除了收看到重複廣播消息Echx(t) 外也可收看到隱密特別報導Idx(t)。At the user receiver 1790, only the repeat broadcast message Echx(t) and the original master broadcast file Em(t) are simultaneously shown in FIG. 17B through the corresponding unpacking processor in the post-processing 640 to enable the second segment of the secret special report Idx. (t) The reorganization is resumed. In addition to receiving the repeated broadcast message Echx(t), the user can also see the secret special report Idx(t).

在圖17A用於預處理630中的Em(t)表示原新聞廣播的母版本, Idx(t)是一小段特別新聞報導。一組4到4 波前覆用的預處理630的配置使其多路輸出顯著強調Echx(t)的特色。其第一輸出為一新聞廣播的子版本。而且此子版本的視頻和音頻外觀與母版新聞廣播Em(t) 的外觀對人類感官而言幾乎完全相同。預處理630剩下的兩條輸入端和三條輸出端全都接地。Em(t) used in pre-processing 630 in Figure 17A represents the parent version of the original news broadcast, and Idx(t) is a short special news story. The configuration of a set of 4 to 4 wavefront pre-processing 630s makes its multi-output significantly emphasize the characteristics of Echx(t). Its first output is a sub-version of a news broadcast. And the video and audio look of this subversion is almost identical to the appearance of the master newscast Em(t) for human senses. The remaining two inputs and the three outputs of pre-processing 630 are all grounded.

原始母版Em(t)和子版本Echx(t) 的新聞廣播消將透過各種管道在不同的時間段,或兩者的組合分佈或廣播出去。這本子版新聞廣播Echx(t) 與母版新聞廣播Em(t)在圖像和聲音質量上的配備基本上應幾乎完全相同。The news broadcasts of the original master Em(t) and the sub-version Echx(t) will be distributed or broadcasted through various pipes at different time periods, or a combination of the two. The sub-version of the news broadcast Echx(t) and the master newscaster Em(t) should be almost identical in terms of image and sound quality.

此外在不同的實施方案中,每本子版複製可以嵌入不同但獨特的附加新聞報導。母版新聞廣播作為唯一的共用數碼信封的功能。嵌入的不同隱密獨特訊息,是 每一新聞廣播子版本的一部分。In addition, in different implementations, each sub-version can embed different but unique additional news stories. Master news broadcasts are the only feature that shares digital envelopes. The different hidden and unique messages embedded are part of each newscast subversion.

對於多次重複廣播,類似的概念可以再擴展到新聞廣播的孫版本。For multiple repeat broadcasts, similar concepts can be extended to the grandchild version of news broadcasts.

在其它實施方案中,可利用預處理630或加封處理的其他兩條接地端口;不再接地而是接入用於認証或其他隱私的附加功能的數碼信號串。In other embodiments, the other two ground ports of the pre-processing 630 or the encapsulation process may be utilized; instead of being grounded, a digital signal string for additional functionality for authentication or other privacy is accessed.

我們已經把加封/解加封技術用新聞廣播的模式來傳遞附加新聞 的例子。同樣的原則也適用於透過雲或其他分佈網路提供的其他隱密獨特IP數碼訊息的傳遞。We have used the seal/unpackage technology to deliver additional news examples using the news broadcast model. The same principles apply to the delivery of other hidden and unique IP digital messages provided through the cloud or other distributed networks.

實施例10Example 10

數碼加封及解加封可利用重複廣播給用戶提供附加的傳送隱密訊息服務的工具。圖18A示出了一組利用廣播和再廣播間隱密的播出其他獨特附加新訊息的架構。作為一個例子,對一段30分鐘的國內原始新聞Em(t) 的母版本將會在播放之前被修改。我們使用數碼加封技術對新聞傳播的副本Idx(t)和Isx(t) 時版本,兩本子版本中都嵌入了第二段獨立的特殊報告Ec(t),其中Isx(t) = M Em(t) + Ec(t) 和Idx(t))= M Em(t) - Ec(t) 而M是放大系數,並應大於或等於1。如在圖18所示在預處理630中的數碼加封處理的結果,新聞傳播兩本子版,  Isx(t) 和Idx(t) ,對人類感官而言與原始母版廣播Em(t) 的視頻和音頻外觀功能幾乎完全相同。所述的第一次廣播將播放兩本子版本中的一本,比如說Isx(t) ,而重新(第二次)廣播將播放另一本子版本Idx(t)。Digital seals and de-seals can be used to provide users with additional tools to deliver hidden messaging services. Figure 18A shows a set of architectures that use other unique additional new messages to be broadcasted implicitly between broadcast and rebroadcast. As an example, the mother version of a 30-minute domestic original news Em(t) will be modified before playback. We use the digital seal technology for the copy of the Idx(t) and Isx(t) versions of the news feed, and the second separate special report Ec(t) is embedded in both subversions, where Isx(t) = M Em( t) + Ec(t) and Idx(t)) = M Em(t) - Ec(t) and M is the amplification factor and should be greater than or equal to 1. As shown in Figure 18, the results of the digital seal process in pre-processing 630, two sub-versions of news dissemination, Isx(t) and Idx(t), video of the original master broadcast Em(t) for human senses It is almost identical to the audio look and feel. The first broadcast will play one of the two sub-versions, such as Isx(t), and the re- (second) broadcast will play another sub-version Idx(t).

在用戶接收機中,  只有當該第一次播放的第一本子版檔案, Isx(t), 和所述第二次播放的第二本子版檔案,Idx(t),同時透過在後處理640中相應的解加封處理器如圖18b所述,特別隱密訊息報告才會被重組恢復出來。 所以第一本子版檔案Isx(t)須在接收中經由適當的緩沖存儲正確地記錄下來。用戶除了有重新廣播消息Idx(t)的服務之外,  也有透過數碼加封而收看特別隱密訊息Ec(t) 廣播的選項服務。In the user receiver, only when the first sub-file is played for the first time, Isx(t), and the second sub-file of the second play, Idx(t), while passing through the post-processing 640 The corresponding unpacking processor is as described in Figure 18b, and the special secret message report will be recombined and restored. Therefore, the first sub-file Isx(t) must be properly recorded in the receiving via appropriate buffer storage. In addition to the service of rebroadcasting the message Idx(t), the user also has an option service for viewing the special secret message Ec(t) broadcast through digital sealing.

許多有線電視服務和衛星電視提供商都同時或幾乎同時透過多種信道提供相同的節目。另一方面,許多廣播平台經由同一頻道多次提供相同節目。這些重複訊息發送或廣播機會可被用於透過數碼加封技術提供的附加訊息或數字文檔。Many cable TV services and satellite TV providers offer the same program simultaneously or almost simultaneously through multiple channels. On the other hand, many broadcast platforms provide the same program multiple times via the same channel. These repeated message transmission or broadcast opportunities can be used for additional messages or digital documents provided by digital sealing technology.

數碼加封的廣播技術更可被擴展至雙向通信。此外,它們也可透過多段廣播,提供傳送一組新數據的機會。該數碼加封的機製,在恢復嵌入的隱密訊息或數據流上,可被配置為具有冗餘功能的。譬如說,隱密訊息或數據流可從四組重播節目中的任何三組就能被重組恢復而播放出來。Digitally sealed broadcast technology can be extended to two-way communication. In addition, they can also provide an opportunity to transmit a new set of data through multiple broadcasts. The digital seal mechanism can be configured to be redundant in restoring embedded secret messages or data streams. For example, a hidden message or data stream can be played back from any of the four groups of replays.

可以想到,透過多段重複廣播節目的設定提供一新數據的隱密傳送方法。 至於普通用戶而言,他們可能會看到相同重複廣播的節目多次。但對於其它具有數碼加封及解加封能力的特別用戶組而言,這些現有服務商已經在使用在重複廣播的多餘信道容量,可以提供新數據,檔案,和訊息傳輸的額外信道容量。由數碼加封技術而產生的附加信道容量更可以用於傳遞更多付費電視節目,股票交換的實時訊息,交通狀況的廣播;等等。It is conceivable to provide a secret transmission method of new data through the setting of a plurality of repeated broadcast programs. As for the average user, they may see the same repeated broadcast of the program multiple times. However, for other special user groups with digital encapsulation and de-encapsulation capabilities, these existing service providers are already using the excess channel capacity for repeated broadcasts, providing additional data capacity for new data, files, and messaging. The additional channel capacity generated by digital encapsulation technology can be used to deliver more pay-TV programs, real-time messages exchanged by stocks, broadcasts of traffic conditions, and more.

實施例11Example 11

保護存儲在雲端私人訊息或數據的隱私權最近成為重要話題。加封及解加封技術可大大的增強雲儲存數據的隱私性包括保護儲存雲端的私人數碼照片。在雲端所存儲的個人訊息是針對用戶的便利性,並不一定是要與其他用戶共享。例如,雲端所存儲加封后的數碼數據可以是原訊息數碼透過用戶辦公室書桌上的PC做的加封處理。此用戶可在將來的任何時段及在任何不同的城市可以從該用戶的手機下載雲端所存儲加封后的數碼數據, 再經由解加封處理重組原私人訊息的數碼數據。類似的數據存儲和檢索重組的概念可能透過該用戶其它個人設備來實現; 譬如平板電腦中的iPad,窗面,銀河注,等。Protecting the privacy of private messages or data stored in the cloud has recently become an important topic. Sealing and unsealing technology can greatly enhance the privacy of cloud storage data, including protecting private digital photos stored in the cloud. The personal information stored in the cloud is user-friendly and does not have to be shared with other users. For example, the digital data stored in the cloud may be the sealing process of the original message digital through the PC on the user's office desk. The user can download the encrypted digital data stored in the cloud from the user's mobile phone at any time in the future and in any different city, and then reassemble the digital data of the original private message through the unsealing process. Similar concepts of data storage and retrieval reorganization may be achieved through other personal devices of the user; for example, iPad in a tablet, window, Galaxy, etc.

圖19示出了輿圖3相似的單一用戶多組設備數據檔案共享概念的簡單框圖;示出可以是個人電腦或筆記本139的私人設備上原存儲數據檔案S(t)至雲端010的例證。圖中有三塊個主要功能模塊;將一組數碼數據檔案存儲在雲端之前先透過預處理130中一套波前覆用而產生兩組覆用後的數碼數據Es(t)和Ed(t),將此兩組覆用後的數碼數據Es(t)和Ed(t)存儲在雲端010,及從雲端中分別檢索出覆用後數據Es(t)和Ed(t)再經由後處理140中一套波前解覆用轉換成原數據檔案S(t)。它們之後。存放在用戶PC或 筆記本139的原數據檔案S(t)是可經由雲端010由該用戶選擇用於他或她的另一設備來共享。一組預處理器130執行了一套2到2波前覆用把原訊息數碼檔案S(t)和數碼信封E5(t)的兩組輸入轉換後而產生兩組數碼輸出Es(t)和Ed(t)。在該套波前覆用轉換中配備了優惠的權重方案,使兩組數碼數據輸出Es(t)和Ed(t)與所選的數碼信封E5(t)的視覺外觀幾乎相同的。我們使用了相同數碼信封E5(t)的視覺外觀來在不同的Es(t)和Ed(t)中包裝原數碼訊息檔案S(t)的。在其它實施例中,我們也可使用有其它外觀的數碼信封的諸如音頻或多媒體格式來嵌入(隱藏)原訊息數碼數據。Figure 19 shows a simplified block diagram of a single user multi-group device data file sharing concept similar to that of Figure 3; showing an illustration of the original storage data file S(t) to cloud 010 on a private device that may be a personal computer or notebook 139. There are three main functional modules in the figure; before storing a set of digital data files in the cloud, the two sets of overwritten digital data Es(t) and Ed(t) are generated through a set of wavefront overrides in the pre-processing 130. The two sets of the overwritten digital data Es(t) and Ed(t) are stored in the cloud 010, and the overwritten data Es(t) and Ed(t) are respectively retrieved from the cloud and then processed through the post processing 140. The set of wavefront solutions is converted into the original data file S(t). After them. The original data file S(t) stored in the user PC or notebook 139 is shared by the user 306 via the cloud 010 for his or her other device. A set of preprocessors 130 performs a set of 2 to 2 wavefronts to convert the two sets of inputs of the original message digital file S(t) and the digital envelope E5(t) to produce two sets of digital outputs Es(t) and Ed(t). In the set of wavefront overlay conversions, a preferential weighting scheme is provided to make the two sets of digital data output Es(t) and Ed(t) almost identical to the visual appearance of the selected digital envelope E5(t). We used the visual appearance of the same digital envelope E5(t) to wrap the original digital message file S(t) in different Es(t) and Ed(t). In other embodiments, we may also embed (hide) the original message digital data using a digital envelope of other appearance, such as an audio or multimedia format.

對某一用戶所有的預期設備而言所選數碼信封都是已知,這是一項非常重要及要注意的假設。無論是Es(t)和Ed(t)都將被上傳到雲端。它們可以被存儲在相同的存儲站點,很可能將是透過各種雲儲存運營商不同的存儲場所。當透過該用戶不同的設備來重組恢復該用戶的原數據時 , 在用戶的其他設備中,譬如一部只能讀的設備149,必須有分別檢索出覆用後數據Es(t)和Ed(t)的功能,然後再對Es(t)和Ed(t) 經由後處理140中進行一套波前解覆用的運作以恢復所存儲的原訊息數碼數據S(t)和所選的數碼信封E5(t)。  S(t)也可能在只能讀的設備149上被顯示。新回收所選的數碼信封E5(t),將可以在當地儲存以備後用。The selected digital envelope is known to all of the intended devices of a user, which is a very important and important assumption. Both Es(t) and Ed(t) will be uploaded to the cloud. They can be stored on the same storage site, most likely through different cloud storage operators' different storage locations. When the original data of the user is reorganized through different devices of the user, in other devices of the user, such as a device 149 that can only be read, the data Es(t) and Ed must be separately retrieved. t) the function, and then perform a set of wavefront decoding operations on Es(t) and Ed(t) via post-processing 140 to recover the stored original message digital data S(t) and the selected digital Envelope E5(t). S(t) may also be displayed on the read only device 149. The newly recycled digital envelope E5(t) will be stored locally for later use.

圖19A示出了輿圖19中所示出那些相似的圖塊例證,簡單框圖表示出用戶多台設備之間; 經由可以是個人電腦或筆記本139的私人設備上傳數據檔案存儲到雲端010的共享的概念。其中有三塊主要模塊;將一組原訊息數碼數據檔案存儲在雲端之前先讓其透過預處理130中一套波前覆用而產生兩組覆用後的數碼數據Es(t)和Ed(t),將此兩組覆用後的數碼數據Es(t)和Ed(t)存儲在雲端010,及從雲端中分別檢索出覆用後數據Es(t)和Ed(t)再經由後處理140中一套波前解覆用的轉換成原數據檔案S(t)。存放在PC或筆記本139的原數據檔案S(t)的是經由雲端010輿由該用戶選擇的另一設備來共享。預處理130對原數據檔案S(t)和所選數碼信封E5(t)的兩條輸入執行一套2到2波前覆用運作,而產生兩路輸出Es(t)和Ed(t)。該套2到2波前覆用並配備了權重優惠的功能,能使兩路數碼數據輸出Es(t)和Ed(t)的視覺外觀與所選數碼信封E5(t)的視覺外觀幾乎相同。我們使用的數碼信封E5(t)的視覺外觀在不同的數碼檔案Es(t)和Ed(t)中以不同的模式包裝了相同的原訊息數碼數據檔案S(t)。在其他實施例中,我們也可以使用數碼信封的其它外觀,諸如音頻或多媒體格式來隱藏(嵌入)原訊息數據。Figure 19A shows a similar block diagram of those shown in Figure 19, with a simple block diagram showing the user between multiple devices; uploading data archives to the cloud 010 via a private device that can be a personal computer or laptop 139 the concept of. There are three main modules; a set of original digital data files are stored in the cloud before they are passed through a set of wavefronts in the pre-processing 130 to generate two sets of overwritten digital data Es(t) and Ed(t). ), the two sets of overwritten digital data Es(t) and Ed(t) are stored in the cloud 010, and the overwritten data Es(t) and Ed(t) are respectively retrieved from the cloud and then processed through the post-processing. A set of wavefront solutions in 140 is converted into the original data file S(t). The original data file S(t) stored in the PC or notebook 139 is shared by another device selected by the user via the cloud 010. The pre-processing 130 performs a set of 2 to 2 wavefront overwrite operations on the two inputs of the original data file S(t) and the selected digital envelope E5(t), and produces two outputs Es(t) and Ed(t). . The set of 2 to 2 wavefronts is equipped with a weight-reward feature that enables the visual appearance of the two digital data outputs Es(t) and Ed(t) to be almost identical to the visual appearance of the selected digital envelope E5(t). . The visual appearance of the digital envelope E5(t) we used encapsulated the same original digital data file S(t) in different modes in different digital files Es(t) and Ed(t). In other embodiments, we may also use other appearances of digital envelopes, such as audio or multimedia formats, to hide (embed) the original message data.

無論是Es(t)和Ed(t)都將被上傳到雲端010。它們,Es(t)和Ed(t),可以被存儲在相同的存儲站點,很可能將是透過各種雲儲存運營商被存儲在不同的存儲場所。Both Es(t) and Ed(t) will be uploaded to the cloud 010. They, Es(t) and Ed(t), can be stored at the same storage site and will likely be stored in different storage locations through various cloud storage operators.

當利用該用戶其他只能讀的設備149之一,譬如只有讀功能的智能手機,來重組恢復用戶的原訊息數據時,該用戶設備必須有獲取儲存在雲端中的一件波前解覆用後檔案Ed(t) 的功能。再和本地存儲的E5(t)同時透過在該用戶的一組只能讀的設備149 (譬如該智能手機)上的後處理140中一套波前解覆用的運作,來恢復所存儲的原訊息數據S(t)。 S(t)的隨後可以顯示在該智能手機上。When one of the other read-only devices 149 of the user, such as a smart phone with only a read function, is used to reassemble and restore the original message data of the user, the user device must obtain a wavefront solution for storage in the cloud. The function of the post file Ed(t). And restoring the stored storage with the locally stored E5(t) simultaneously through a set of wavefront decoding operations in the post-processing 140 of the user's set of only read-only devices 149 (such as the smart phone) Original message data S(t). The S(t) can then be displayed on the smartphone.

圖19B示出了輿圖19中所示出那些相似的圖塊例證,簡單框圖表示出用戶多台設備之間; 經由可以是個人電腦或筆記本139的私人設備上傳數據檔案存儲到雲端010的共享的概念。  其中有三塊主要模塊;將一組原訊息數碼數據檔案存儲在雲端之前先讓其透過預處理130中一套波前覆用而產生兩組覆用後的數碼數據Es(t)和Ed(t),將此兩組覆用後的數碼數據Es(t)和Ed(t)存儲在雲端010,及從雲端中分別檢索出覆用後數據Es(t)和Ed(t)再經由後處理140中一套波前解覆用轉換成原數據檔案S(t)。存放在PC或筆記本139的原數據檔案S(t)的是經由雲端010輿由該用戶選擇的另一設備來共享。預處理130對原數據檔案S(t)和所選數碼信封E5(t)的兩條輸入執行一套2到2波前覆用運作,而產生兩路輸出Es(t)和Ed(t)。該套2到2波前覆用並配備了權重優惠的功能,能使兩路數碼數據輸出Es(t)和Ed(t)的視覺外觀與所選數碼信封E5(t)的視覺外觀幾乎相同。我們使用的數碼信封E5(t)的視覺外觀在不同的數碼檔案Es(t)和Ed(t)中以不同的模式包裝了相同的原訊息數碼數據檔案S(t)。在其他實施例中,我們也可以使用數碼信封的其它外觀,諸如音頻或多媒體格式來隱藏(嵌入)原訊息數據。Figure 19B shows a similar block diagram of those shown in Figure 19, with a simple block diagram showing the user between multiple devices; uploading data archives to the cloud 010 via a private device that can be a personal computer or laptop 139 the concept of. There are three main modules; a set of original digital data files are stored in the cloud before they are passed through a set of wavefronts in the pre-processing 130 to generate two sets of overwritten digital data Es(t) and Ed(t). ), the two sets of overwritten digital data Es(t) and Ed(t) are stored in the cloud 010, and the overwritten data Es(t) and Ed(t) are respectively retrieved from the cloud and then processed through the post-processing. A set of wavefront solutions in 140 is converted into the original data file S(t). The original data file S(t) stored in the PC or notebook 139 is shared by another device selected by the user via the cloud 010. The pre-processing 130 performs a set of 2 to 2 wavefront overwrite operations on the two inputs of the original data file S(t) and the selected digital envelope E5(t), and produces two outputs Es(t) and Ed(t). . The set of 2 to 2 wavefronts is equipped with a weight-reward feature that enables the visual appearance of the two digital data outputs Es(t) and Ed(t) to be almost identical to the visual appearance of the selected digital envelope E5(t). . The visual appearance of the digital envelope E5(t) we used encapsulated the same original digital data file S(t) in different modes in different digital files Es(t) and Ed(t). In other embodiments, we may also use other appearances of digital envelopes, such as audio or multimedia formats, to hide (embed) the original message data.

無論是Es(t)和Ed(t)將被上傳到雲端。它們可存儲在相同的存儲站點,也很可能透過各種雲儲存運營商存儲在不同的存儲場所。Both Es(t) and Ed(t) will be uploaded to the cloud. They can be stored on the same storage site, and are likely to be stored in different storage locations through various cloud storage operators.

當透過不同的設備恢復用戶的原訊息數據,該用戶設備必須有從雲端中獲取一件覆用後檔案Es(t)的功能,然後再使用Es(t)和存儲的E5(t)作為輸入在該只能讀的設備149,譬如該智能電話上,經由後處理140來進行波前解覆用以重組恢復所存儲的原訊息數據S(t)。 S(t)隨後可以顯示在該智能手機上。When restoring the user's original message data through different devices, the user device must have the function of obtaining an overwritten file Es(t) from the cloud, and then use Es(t) and stored E5(t) as input. On the read-only device 149, such as the smart phone, wavefront decoding is performed via post-processing 140 for recombining the restored original message data S(t). S(t) can then be displayed on the smartphone.

圖19C示出了輿圖19中所示出那些相似的圖塊例證,簡單框圖表示出用戶多台設備之間; 可以是經由個人電腦或筆記本139的私人設備上傳數據檔案存儲到雲端010的共享的概念。 其中有三塊主要模塊;將一組原訊息數碼數據檔案存儲在雲端之前先讓其透過預處理130中一套波前覆用而產生兩組覆用後的數碼數據Es(t)和Ed(t),將此兩組覆用後的數碼數據Es(t)或Ed(t)中的一组存儲在雲端010,及從雲端中檢索出的覆用後數據Es(t)或Ed(t)同時利用原數碼信封 E5(t)再經由後處理140中波前解覆用轉換成原數據檔案S(t)。存放在PC或筆記本 139 的原數據檔案S(t)的是經由雲端010輿由該用戶選擇的另一設備來共享。預處理130對原數據檔案S(t)和所選數碼信封E5(t)的兩條輸入執行一套2到2波前覆用運作,而產生兩路輸出Es(t)和Ed(t)。該套2到2波前覆用並配備了權重優惠的功能,能使兩路數碼數據輸出Es(t)和Ed(t)的視覺外觀與所選數碼信封E5(t)的視覺外觀幾乎相同。我們使用的數碼信封E5(t)的視覺外觀在不同的數碼檔案Es(t)和Ed(t)中以不同的模式包裝了相同的原訊息數碼數據檔案S(t)。在其他實施例中,我們也可以使用數碼信封的其它外觀,諸如音頻或多媒體格式來隱藏(嵌入)原訊息數據。Figure 19C shows an example of a tile similar to those shown in Figure 19, a simple block diagram showing the user between multiple devices; a private device that can be uploaded via a personal computer or laptop 139 to the cloud 010 share the concept of. There are three main modules; a set of original digital data files are stored in the cloud before they are passed through a set of wavefronts in the pre-processing 130 to generate two sets of overwritten digital data Es(t) and Ed(t). ), one of the two sets of overwritten digital data Es(t) or Ed(t) is stored in the cloud 010, and the post-recovered data Es(t) or Ed(t) retrieved from the cloud. At the same time, the original digital envelope E5(t) is converted into the original data file S(t) via the wavefront decoding in the post-processing 140. The original data file S(t) stored in the PC or notebook 139 is shared by another device selected by the user via the cloud 010. The pre-processing 130 performs a set of 2 to 2 wavefront overwrite operations on the two inputs of the original data file S(t) and the selected digital envelope E5(t), and produces two outputs Es(t) and Ed(t). . The set of 2 to 2 wavefronts is equipped with a weight-reward feature that enables the visual appearance of the two digital data outputs Es(t) and Ed(t) to be almost identical to the visual appearance of the selected digital envelope E5(t). . The visual appearance of the digital envelope E5(t) we used encapsulated the same original digital data file S(t) in different modes in different digital files Es(t) and Ed(t). In other embodiments, we may also use other appearances of digital envelopes, such as audio or multimedia formats, to hide (embed) the original message data.

Es(t)和Ed(t)中只有一件會被上傳到雲端010。因此要在沒有預先已知數碼信封的條件下從在雲儲存和傳輸的訊息重構隱藏(嵌入)在Es(t)或Ed(t)中的數碼訊息檔案S(t)是不可能的。Only one of Es(t) and Ed(t) will be uploaded to the cloud 010. Therefore, it is impossible to reconstruct the digital message file S(t) hidden (embedded) in Es(t) or Ed(t) from the messages stored and transmitted in the cloud without the prior known digital envelope.

當透過不同的設備來恢復用戶的原訊息數據,該用戶設備必須有從雲端檢索中獲取第一件覆用後檔案Es(t)的功能,然後再使用Es(t)和存儲在該只能讀的設備149上的E5(t),譬如在該智能電話上,來進行後處理140中波前解覆用以重組恢復所存儲的原訊息數據S(t)。 S(t)隨後可以顯示在該智能手機上。When restoring the user's original message data through different devices, the user device must have the function of obtaining the first file Es(t) after the file is retrieved from the cloud, and then use Es(t) and store it in the E5(t) on the read device 149, such as on the smart phone, performs post-processing 140 wavefront cancellation for recombination to recover the stored original message data S(t). S(t) can then be displayed on the smartphone.

實施方案12Embodiment 12

圖20描繪了一幅共享私人訊息隱私保護的頂層功能,其中某用戶在雲中傳輸和存儲的數據可與多個該用戶設備共享。雲計算讓用戶可在任何時間從世界任何地方拿到該用戶所需的應用程式和檔案,從桌面的束縛中解放出來,也可促進團隊用戶間的協作。但是多用戶雲計算共享並不是可適用於所有的應用程式;這類基於網路的計算有優點也有缺點。另一方面,許多的雲計算應用訊息可在某一用戶的多套設備之間共享 。 所存儲的有隱私訊息的個人數據,或為用戶自己方便而收集的數據,都不是要與其他人共享的。數碼加封和解加封的技術可增強用於雲端010的私人數據存儲和傳輸的隱私保護。在圖20中例子的特徵在於所有儲存在雲端010的都是經由在用戶的辦公室書桌上的PC或筆記本139中先被加封處理後數據。該用戶可在以後的時間從不同的城市透過雲端010檢索所存儲的數據或視頻剪輯,再從該用戶手機,或ipad ,或只能讀的設備149重構視頻剪輯。非常重要也是要注意的就是用於加封及解加封的數碼信封對該用戶的所有設備而言是已知的或是預先設定的。Figure 20 depicts a top-level function for sharing private message privacy protection in which data transmitted and stored by a user in the cloud can be shared with multiple user devices. Cloud computing allows users to get the applications and files they need from anywhere in the world at any time, freeing them from the constraints of the desktop, and facilitating collaboration among team users. But multi-user cloud computing sharing is not suitable for all applications; such network-based computing has advantages and disadvantages. On the other hand, many cloud computing application messages can be shared between multiple devices of a certain user. Personal data stored with private messages, or data collected for the convenience of the user, is not shared with others. Digital encapsulation and de-encapsulation technology enhances privacy protection for private data storage and transmission for Cloud 010. The feature of the example in Fig. 20 is that all stored in the cloud 010 are processed by the PC or notebook 139 on the user's office desk. The user can retrieve the stored data or video clips from the different cities through the cloud 010 at a later time, and reconstruct the video clips from the user's mobile phone, or the ipad, or the read-only device 149. It is also important to note that the digital envelopes used for sealing and unsealing are known or pre-set for all of the user's devices.

圖20A示出了如圖19中那些相似的的功能塊,在用戶的多台設備間共享儲存在雲端010數碼數據檔案的概念; 簡單框圖上例證示出的私人設備可以是一部個人電腦或筆記本139。這裡有三片主要的功能塊,預處理230或加封處理是透過一套M-對-M波前覆用的預處理230來轉換原訊息數碼成多組覆用後的數碼數據的功能,再將該多組覆用後的數碼數據存儲在雲端010。後處理240或解加封處理是經由一套M-對-M波前解覆用對從雲中拿取到的覆用後數碼數據做轉換處理來還原原訊息數碼。Figure 20A shows a similar functional block as those in Figure 19, sharing the concept of storing digital data files in the cloud 010 among multiple devices of the user; the private device illustrated on the simple block diagram can be a personal computer Or notebook 139. There are three main function blocks here. The pre-processing 230 or the sealing process is a function of converting the original message digital into multiple sets of the overwritten digital data through a pre-processing 230 of the M-pair-M wavefront. The plurality of sets of the overwritten digital data are stored in the cloud 010. The post-processing 240 or de-seal processing is to restore the original message digital by performing a conversion process on the over-received digital data taken from the cloud via a set of M-pair-M wavefront solutions.

在PC或筆記本 139中的一件所存儲的訊息數據檔案S(t)可經由用戶的自己選擇,透過雲端與該用戶的其他設備共享。S(t)由一件分割設備229被分割成的M-1組;此分割設備229可以是一個TDM分路器或一套串行-對-並行轉換器。一套M-對-M的預處理230所選的M-1個輸入端口結到M-1組分割後的信息數而其最後一個輸入接到從本地候選信封文檔180中選出的數碼信封, 然後對此M組數碼做波前覆用轉換。 所產生的M路覆用後輸出。在此組波前覆用中還配備了優惠的權重方案而使M組輸出數碼數據的視覺外觀幾乎輿所選數碼信封相同視覺外觀的功能。我們使用的是所選數碼信封的視覺外觀來包裝中的原訊息數碼數據檔案S(t);以不同的模式用在所有不同的波前覆用後的檔案。 在其它實施例中,我們可以使用數碼信封的其它外觀諸如音頻或多媒體格式來隱藏或嵌入原訊息數碼數據。A stored message data file S(t) in a PC or notebook 139 can be shared with other devices of the user via the cloud by the user's own selection. S(t) is divided into M-1 groups by a piece of dividing device 229; this dividing device 229 can be a TDM splitter or a set of serial-to-parallel converters. A set of M-to-M pre-processing 230 selected M-1 input ports to the M-1 group of divided information and the last input to the digital envelope selected from the local candidate envelope document 180, Then do the wavefront over conversion for this M group of digital. The generated M path is output and output. In this group of wavefront overrides, a preferential weighting scheme is also provided to enable the M group to output a digital data with a visual appearance that is almost the same as the visual appearance of the selected digital envelope. We use the visual appearance of the selected digital envelope to store the original message digital data file S(t); it is used in all different wavefront-applied files in different modes. In other embodiments, we may use other forms of digital envelopes, such as audio or multimedia formats, to hide or embed the original message digital data.

波前覆用後所有的M條輸出將同時透過WiFi和手機網路被上傳到雲端。它們有可能被存儲在相同的存儲站點,但也很可能透過不同雲儲運營商被存在不同的儲存場所。After the wavefront is overwritten, all M outputs will be uploaded to the cloud via WiFi and mobile networks. They may be stored at the same storage site, but it is also likely that different storage locations exist through different cloud storage operators.

當重組恢復用戶的原訊息數據,該用戶必須從雲端的M組覆用後數碼檔案檢索任何M-1組,然後利用檢索到的M-1的覆用後數據檔案及一組已選的數碼信封在後處理240中執行一套M-到-M 波前解覆用;此組已選的數碼信封是儲存在該用戶的智能手機159或其它只能讀的設備149上, 例如圖20所示的一件iPad,存在候選信封文檔180中的數碼信封。被置於在後處理240中此套波前解覆用之後的一組M-1對1解分割過程241可將重組M-1組原分割數碼檔案來恢復一組原訊息數碼數據S(t)。重組復原的訊息數碼 S(t)也可能在只能讀的設備149如iPad上顯示。When the original message data of the user is reorganized and restored, the user must retrieve any M-1 group from the digital file of the M group in the cloud, and then use the retrieved M-1 data file and a selected set of selected numbers. The envelope performs a set of M-to-M wavefront cancellations in post-processing 240; the set of selected digital envelopes is stored on the user's smartphone 159 or other read-only device 149, such as Figure 20. The illustrated one piece of iPad has a digital envelope in the candidate envelope document 180. A set of M-1 to 1 de-segmentation processes 241 placed after the set of wavefronts in post-processing 240 can reconstruct the original M-1 group to reconstruct a set of original message digital data S(t ). The reorganized restored message digital S(t) may also be displayed on a read-only device 149 such as an iPad.

圖20B示出了如圖20A中那些相似的的功能塊,在用戶的多台設備間共享儲存在雲端010數碼數據檔案的概念; 簡單框圖上例證示出的私人設備可以是一部智能手機。這裡有三件私人設備;第一件是具有“寫”及“讀”能力的智能手機159,其他兩件都只有讀取能力設備。第二件的私人設備是一台只能讀的設備149;一台只能讀而不能寫的智能手機, 第三件的私人設備是另一台只能讀的設備149; 是一件iPad。在智能手機159中的書寫功能和圖20A中預處理230或加封處理是類似的。 是在分割後的原訊息數碼存儲在雲端010之前,透過預處理230中一套M-對-M波前覆用來轉換多組分割後的原訊息數碼小串而成為多組覆用後的數碼數據。將該多組覆用後的數碼數據存儲在雲端010,這智能手機159和多台只能讀的設備149的閱讀能力及後處理240或解加封是類似的。是經由在後處理240中一套M-對-M波前解覆用對從雲中拿取到的覆用後數碼數據做轉換處理來還原原訊息數碼。Figure 20B shows a functional block similar to those in Figure 20A, sharing the concept of storing digital data files in the cloud 010 among multiple devices of the user; the private device illustrated on the simple block diagram may be a smart phone . There are three pieces of personal equipment here; the first one is a smartphone 159 with "write" and "read" capabilities, and the other two have read-only capabilities. The second piece of personal equipment is a read-only device 149; a smart phone that can only be read but not written, and the third private device is another read-only device 149; an iPad. The writing function in the smartphone 159 is similar to the pre-processing 230 or the sealing process in Fig. 20A. After the segmented original message is stored in the cloud 010, a set of M-pair-M waves in the pre-processing 230 is used to convert the plurality of sets of the divided original digital sub-strings into multiple sets of used digital data. The plurality of sets of overwritten digital data are stored in the cloud 010, and the reading capabilities and post-processing 240 or de-sealing of the smart phone 159 and the plurality of read-only devices 149 are similar. The original message number is restored by performing a conversion process on the M-to-M wavefront solution in the post-processing 240 by using the over-received digital data taken from the cloud.

圖20C描繪了相似於圖20A示出的那些圖塊。圖20C作為例證之中一個用戶的多個設備共享的概念。它表明的“寫入”功能 ,關於如何經由智能手機 159在雲端010存儲原信息數據文件,和經由相同的智能手機159或從一件不同的設備在一不同的時間或在不同的城市,從雲端“閱讀”同一數據文件的簡單框圖。在”寫入”的過程,首先由一組分割設備229,譬如是一台TDM分路器,把一件數碼數據文件S(t)分割成的M-1組原數碼數據小組或小串,在經由一套預處理230執行一種M-對-M波前覆用轉換;  利用M-1組分割後原數碼數據小串做為此波前覆用轉換的M-1個輸入,再從本地候選信封文檔180中選出的數碼信封作為最後一個剩余輸入端口的輸入數碼串。此波前覆用轉換產生的M條波前覆用後輸出。在此組波前覆用中還配備了優惠的權重方案而使M組輸出數碼數據的視覺外觀和所選數碼信封之視覺外觀幾乎相同的功能。檔案加封功能利用所選數碼信封的視覺外觀來包裝不同的原訊息數碼檔案S(t)的模式。在其它實施例中,我們可以使用數碼信封的其它外觀;諸如音頻或多媒體格式,來嵌入(隱藏)原訊息數碼檔案。該智能手機159具有可以獨立的做“書寫”(上載)和“閱讀”(下載)功能。Figure 20C depicts those tiles similar to those shown in Figure 20A. Figure 20C is a concept of sharing of multiple devices of one user among the illustrations. It indicates the "write" function on how to store the original information data file in the cloud 010 via the smartphone 159, and via the same smartphone 159 or from a different device at a different time or in a different city, from A simple block diagram of the cloud "reading" the same data file. In the process of "writing", a group of dividing devices 229, such as a TDM splitter, first divides a digital data file S(t) into groups of M-1 original digital data or small strings. Performing an M-pair-M wavefront pre-over conversion via a set of pre-processing 230; using the M-1 group-divided original digital data string as the M-1 inputs for this wavefront overlay conversion, and then from the local candidate envelope The digital envelope selected in document 180 serves as the input digital string for the last remaining input port. The M wavefronts generated by this wavefront over-conversion are over-applied and output. This group of wavefront overrides is also equipped with a preferential weighting scheme to make the M group output digital data with a visual appearance that is almost identical to the visual appearance of the selected digital envelope. The File Sealing feature uses the visual appearance of the selected digital envelope to wrap the different original message digital file S(t) patterns. In other embodiments, we can use other appearances of digital envelopes, such as audio or multimedia formats, to embed (hide) the original message digital file. The smartphone 159 has the functions of "writing" (uploading) and "reading" (downloading) independently.

波前覆用所有的M輸出將同時透過WiFi和手機網路011被上傳到雲端010。它們有可能被存儲在相同的存儲站點,也很可能透過不同雲儲運營商被存在不同的儲存場所。All M outputs of the wavefront overlay will be uploaded to the cloud 010 via WiFi and mobile network 011 at the same time. They may be stored at the same storage site, and are likely to be stored in different storage locations through different cloud storage operators.

當重組恢復用戶的原訊息數據,該用戶必須從雲端的M組覆用後數碼檔案檢索任何M-1組,然後利用檢索到的M-1的覆用後數據檔案及一組已選的數碼信封在後處理240中執行一套M-到-M 波前解覆用;此組已選的數碼信封是儲存在該用戶的智能手機159或其它只能讀的設備149上,例如圖20所示的一件iPad,存在候選信封文檔180中的數碼信封。 被置於此套在後處理240中的波前解覆用之後的一組M-1對1解分割過程241可將重組M-1組分割後的原數碼小串來恢復一組原訊息數碼數據S(t)。重組復原的訊息數碼 S(t)也可能在其它只能讀的設備149(如iPad)上顯示。 這是一個有冗餘功能的例子。When the original message data of the user is reorganized and restored, the user must retrieve any M-1 group from the digital file of the M group in the cloud, and then use the retrieved M-1 data file and a selected set of selected numbers. The envelope performs a set of M-to-M wavefront cancellations in post-processing 240; the set of selected digital envelopes is stored on the user's smartphone 159 or other read-only device 149, such as Figure 20. The illustrated one piece of iPad has a digital envelope in the candidate envelope document 180. A set of M-1 to 1 de-segmentation processes 241 placed after the wavefront cancellation in the post-processing 240 can reconstruct the original digital string of the reconstructed M-1 group to recover a set of original digital data. S(t). The reorganized restored message digital S(t) may also be displayed on other read-only devices 149 (such as an iPad). This is an example of a redundant function.

在另一方面,當某一用戶忘了該用戶各種裝置之間的同步設定或是其他原因以至在可用的檢索裝置上沒有加封時所選定的數碼信封,用戶可使用所有M組存儲在雲端的覆用後數碼,可同時重組恢復的原數據檔案S(t)和所選的數碼信封。這將是用於經由雲端拿回及重組用戶所選的數碼信封的技術。恢復的數碼信封然後可存儲在本地再應用到將來檢索存儲在雲端不同的加封數碼檔案。On the other hand, when a user forgets the synchronization setting between the various devices of the user or other reasons, and the digital envelope selected when the available retrieval device is not sealed, the user can use all the M groups stored in the cloud. After the digital is overwritten, the restored original data file S(t) and the selected digital envelope can be recombined at the same time. This will be the technology used to retrieve and reorganize the digital envelopes selected by the user via the cloud. The recovered digital envelope can then be stored locally and then applied to future retrieval of different sealed digital files stored in the cloud.

此外,當數碼信封變得可用於檢索存儲的數據檔案,這也是可用在用戶偶爾地或連續地檢查所存儲數碼數據的完整性。用戶可將拿到所有M組存儲在雲端的加封后檔案,並執行波前解覆用以再生S′(t)和一個再生的數碼信封。用戶可以再用再生的數碼信封輿原有已知的數碼信封比較。當比較的結果是相同時,它是一個可驗証所還原的數據檔案S′(t)就是原訊息數碼S(t)的很好指標。另一方面,若比較的結果有差異,它的結果表明再生的S′(t)已受損。In addition, when digital envelopes become available for retrieving stored data archives, this can also be used by the user to check the integrity of the stored digital data occasionally or continuously. The user can get all the M files stored in the cloud's sealed file and perform wavefront decoding to regenerate S'(t) and a regenerated digital envelope. Users can then use a regenerated digital envelope to compare the original known digital envelopes. When the result of the comparison is the same, it is a good indicator that the verified data file S'(t) is the original message number S(t). On the other hand, if the results of the comparison are different, its results indicate that the regenerated S'(t) has been impaired.

在其它實施方案中,一組要“書寫〞到雲端010的數據檔案S(t) 首先由分割設備229,可以是TDM分路器,分割成的M-x小組。再利用預處理230對S(t)分割成的M-x小組及從本地在候選信封文檔180中選出的y組數碼信封當做M組輸入的部分來執行一套M對-M波前覆用,而產生M組波前覆用輸出。選擇的M組輸入端口包括M-x組訊息輸入, y組數碼信封檔案,及 y-x組接地輸入。其中x 和y 都是正整數而且y ³ x ³ 1。在此組波前覆用中還配備了優惠的權重方案而使M組輸出數碼數據的視覺外觀幾乎輿所選數碼信封之一相同的功能。檔案加封功能利用所選數碼信封的視覺外觀來包裝不同的原訊息數碼檔案S(t)的模式。在其它實施例中,我們可以使用數碼信封的其它外觀;諸如音頻或多媒體格式,來嵌入(隱藏)原訊息數碼檔案。該智能手機159,如圖20B及20C 中所示,可以做“書寫”(上載)和“閱讀”(下載)獨立。另外,對某一用戶及該用戶所有可預期的設備而言,數碼信封是已知用的而且是預先設定的。 這是非常重要的, 也是要注意的。In other embodiments, a set of data files S(t) to be "written to the cloud 010" is first divided into M-x groups by a segmentation device 229, which may be a TDM splitter. The preprocessing 230 is used to perform an M-pair-M wavefront override on the Mx group into which S(t) is segmented and the y-group digital envelope selected from the candidate envelope document 180 as part of the M group input. Generate M sets of wavefront override outputs. The selected M group input ports include M-x group message input, y group digital envelope file, and y-x group ground input. Where x and y are both positive integers and y 3 x 3 1. This group of wavefront overrides is also equipped with a preferential weighting scheme so that the visual appearance of the M group output digital data is almost the same as that of one of the selected digital envelopes. The File Sealing feature uses the visual appearance of the selected digital envelope to wrap the different original message digital file S(t) patterns. In other embodiments, we can use other appearances of digital envelopes, such as audio or multimedia formats, to embed (hide) the original message digital file. The smartphone 159, as shown in Figs. 20B and 20C, can be "written" (uploaded) and "read" (downloaded) independently. In addition, digital envelopes are known and pre-set for a user and all of the user's predictable devices. This is very important and should be noted.

波前覆用所有的M輸出將同時透過WiFi和手機網路被上傳到雲端。它們有可能被存儲在相同的存儲站點,也很可能透過不同雲儲運營商被存在不同的儲存場所。All M outputs of the wavefront overlay will be uploaded to the cloud via WiFi and mobile networks. They may be stored at the same storage site, and are likely to be stored in different storage locations through different cloud storage operators.

當重組恢復用戶的原訊息數據,該用戶必須從雲端的M組覆用後數碼檔案檢索任何M-1組,然後利用檢索到的M-1的覆用後數據檔案及一組已選的數碼信封在後處理240中執行一套M-到-M 波前解覆用;此組已選的數碼信封是儲存在該用戶的智能手機159或其它只能讀的設備149上,例如圖20所示的一件iPad,存在候選信封文檔180中的數碼信封。被置於在後處理240中此套波前解覆用之後的一組M-1對1解分割過程241可將重組M-1組分割後的原數碼小串來恢復一組原訊息數碼數據S(t)。重組復原的訊息數碼 S(t)也可能在其它只能讀的設備149(如iPad)上顯示。 這是一個有冗餘功能的例子。When the original message data of the user is reorganized and restored, the user must retrieve any M-1 group from the digital file of the M group in the cloud, and then use the retrieved M-1 data file and a selected set of selected numbers. The envelope performs a set of M-to-M wavefront cancellations in post-processing 240; the set of selected digital envelopes is stored on the user's smartphone 159 or other read-only device 149, such as Figure 20. The illustrated one piece of iPad has a digital envelope in the candidate envelope document 180. A set of M-1 to 1 de-segmentation processes 241 placed after the set of wavefronts in post-processing 240 may reconstruct the original digital string of the reconstructed M-1 group to recover a set of original digital data S. (t). The reorganized restored message digital S(t) may also be displayed on other read-only devices 149 (such as an iPad). This is an example of a redundant function.

在另一方面,當某一用戶忘了該用戶各種裝置之間的同步設定或是其他原因以至在可用的檢索裝置上沒有加封時所選定的數碼信封,用戶可使用所有M組存儲在雲端的覆用後數碼,可同時用來重組恢復的原數據檔案S(t)和所選的數碼信封。這將是用於經由雲端拿回及重組用戶所選的數碼信封的技術。恢復的數碼信封然後可存儲在本地再應用到將來檢索存儲在雲端不同的加封數碼檔案。On the other hand, when a user forgets the synchronization setting between the various devices of the user or other reasons, and the digital envelope selected when the available retrieval device is not sealed, the user can use all the M groups stored in the cloud. After the digital is overwritten, it can be used to recombine the restored original data file S(t) and the selected digital envelope. This will be the technology used to retrieve and reorganize the digital envelopes selected by the user via the cloud. The recovered digital envelope can then be stored locally and then applied to future retrieval of different sealed digital files stored in the cloud.

此外,當數碼信封變得可用於檢索存儲的數據檔案,這也是可用在用戶偶爾地或連續地檢查所存儲數碼數據的完整性。用戶可將拿到所有M組存儲在雲端的加封后檔案,並執行波前解覆用以再生S′(t)和一個再生的數碼信封。用戶可以再用再生的數碼信封輿原有已知的數碼信封比較。當比較的結果是相同時,它是一個很好的指標可驗証所還原的數據檔案S′(t)就是原訊息數碼S(t)。另一方面,當比較的結果有差異,它的結果表明再生的S′(t)已受損。In addition, when digital envelopes become available for retrieving stored data archives, this can also be used by the user to check the integrity of the stored digital data occasionally or continuously. The user can get all the M files stored in the cloud's sealed file and perform wavefront decoding to regenerate S'(t) and a regenerated digital envelope. Users can then use a regenerated digital envelope to compare the original known digital envelopes. When the result of the comparison is the same, it is a good indicator to verify that the restored data file S'(t) is the original message number S(t). On the other hand, when the results of the comparison differ, its results indicate that the regenerated S'(t) has been impaired.

在其它實施方案中,一組要“書寫〞到雲端010的數據檔案S(t) 首先由分割設備229,可以是TDM分路器,分割成的M-x小組。再利用預處理230 對S(t)分割成的M-x小組及從本地候選信封文檔180選出的y組數碼信封當做M組輸入的部分來執行一套M對-M波前覆用,而產生M組波前覆用輸出。選擇的M組輸入端口包括M-x組訊息輸入, y組數碼信封檔案,及 y-x組接地輸入。其中x和y 都是正整數而且y ³ x ³ 1。在此組波前覆用中還配備了優惠的權重方案而使M組輸出數碼數據的視覺外觀幾乎輿所選數碼信封之一相同的功能。檔案加封功能利用所選數碼信封的視覺外觀來包裝不同的原訊息數碼檔案S(t)的模式。在其它實施例中,我們可以使用數碼信封的其它外觀;諸如音頻或多媒體格式,來嵌入(隱藏)原訊息數碼檔案。該智能手機159,如圖20B及20C中所示,可做獨立“書寫”(上載)和“閱讀”(下載)。In other embodiments, a set of data files S(t) to be "written to the cloud 010" is first divided into M-x groups by a segmentation device 229, which may be a TDM splitter. The pre-processing 230 is used to perform an M-pair-M wavefront override on the Mx group into which S(t) is segmented and the y-group digital envelope selected from the local candidate envelope document 180 as part of the M-group input, and generate M The group wavefront is overwritten with the output. The selected M group input ports include M-x group message input, y group digital envelope file, and y-x group ground input. Where x and y are both positive integers and y 3 x 3 1. This group of wavefront overrides is also equipped with a preferential weighting scheme so that the visual appearance of the M group output digital data is almost the same as that of one of the selected digital envelopes. The File Sealing feature uses the visual appearance of the selected digital envelope to wrap the different original message digital file S(t) patterns. In other embodiments, we can use other appearances of digital envelopes, such as audio or multimedia formats, to embed (hide) the original message digital file. The smartphone 159, as shown in Figures 20B and 20C, can be independently "written" (uploaded) and "read" (downloaded).

在M組的覆用輸出中只有M-x組才會同時透過不同的WiFi和手機網路分別上傳到雲端。它們可以被存儲在相同的存儲站點,也很可能將是透過不同雲存營運商儲存在不同的存儲場所。Only the M-x group in the M group's override output will be uploaded to the cloud through different WiFi and mobile networks. They can be stored on the same storage site and will likely be stored in different storage locations through different cloud storage operators.

當恢復某用戶的原訊息數據時,該用戶應從雲端檢索出M-x組的波前覆用後的數碼檔案,然後對檢索到的M-x組的覆用後數碼檔案,y-x組的零輸入,和y組所選已知的數碼信封在後處理240中進行一套M對M 波前解覆用處理。所選的已知數碼信封都會存儲在用戶智能手機159或其它只能讀的設備149的候選信封文檔180中;比方說如圖20所示的一個iPad 中。在後處理240中該套波前解覆用處理之後,一組解分割過程241 會把M-x組解覆用後數碼串重組恢復成存儲的原訊息數碼數據S(t),然後把原訊息數碼S(t)也可能在其它只能讀的設備149(如iPad)上顯示出來。在此實施例中沒有展示波前覆用及波前解覆用的冗餘性。When restoring a user's original message data, the user should retrieve the wavefront-applied digital file of the Mx group from the cloud, and then the digital file of the retrieved Mx group, the zero input of the yx group, and y The group selected known digital envelopes are subjected to a set of M-to-M wavefront unwrapping processes in post-processing 240. The selected known digital envelopes are stored in the candidate envelope document 180 of the user smartphone 159 or other read-only device 149; for example, in an iPad as shown in FIG. After the set of wavefront decoding processes in post-processing 240, a set of de-segmentation process 241 will reconstruct the Mx group after the digital string recombination into the stored original message digital data S(t), and then the original message digital S(t) may also be displayed on other read-only devices 149 (such as an iPad). The redundancy for wavefront coverage and wavefront cancellation is not shown in this embodiment.

另外,也可以經由WiFi和蜂窩電話兩類網路結口同時上載N組覆用輸出到雲端,其中N是一個大於M-x的整數。它們可以被存儲在相同的存儲站點,很可能透過不同雲儲運營商儲存在不同的存儲場所。這種儲存模式會有N - (M-x) 的冗餘。當需恢復某原用戶的數據時,該用戶只須從雲中N組存儲檔案中拿回M-x組檔案,然後在後處理240中執行一套M-到-M波前解覆用及利用已知的y-x組的零輸入及y組從本地儲存在候選信封文檔180中選出的數碼信封,來重組M-x 原數碼數據檔案。候選信封文檔180是在用戶的智能手機 159或其它只能讀的設備149上,譬如說一件如圖20A中所示的iPad上。在透過在後處理240中一套波前解覆用操作後再經由一組M-x到1的解分割過程241就能恢復可以在其它只能讀的設備149(如iPad)上顯示的原訊息數據S(t)。In addition, N sets of overlay output can also be uploaded to the cloud simultaneously through the two types of network interfaces of WiFi and cellular phones, where N is an integer greater than M-x. They can be stored on the same storage site and are likely to be stored in different storage locations through different cloud storage operators. This storage mode has N - (M-x) redundancy. When it is necessary to restore the data of an original user, the user only needs to retrieve the Mx group file from the N group storage files in the cloud, and then perform a set of M-to-M wavefront decoding and utilization in the post-processing 240. The zero input of the known yx group and the y group reorganize the original digital data file of the Mx from the digital envelope selected locally in the candidate envelope document 180. The candidate envelope document 180 is on the user's smartphone 159 or other read-only device 149, such as an iPad as shown in Figure 20A. The original message data that can be displayed on other read-only devices 149 (such as an iPad) can be recovered via a set of Mx to 1 de-segmentation processes 241 after a set of wavefront decoding operations in post-processing 240. S(t).

補充意見Additional comments

至於在上述有關波前覆用的應用中,某一波前覆用器也可用第一組非正交矩陣替代執行多路輸入信號的波前覆用轉換。至於在上述有關波前解覆用的應用中,某一波前解覆用器可用第二非正交矩陣替代執行多路輸入信號的波前解覆用轉換。其中,第二非正交矩陣是第一非正交矩陣的反矩陣。In the above application for wavefront override, a wavefront predepator can also replace the wavefront override conversion of the multiple input signals with the first set of non-orthogonal matrices. As for the above-described application for wavefront cancellation, a wavefront demultiplexer can replace the wavefront solution conversion for performing multiple input signals with a second non-orthogonal matrix. The second non-orthogonal matrix is an inverse matrix of the first non-orthogonal matrix.

上述的組件,步驟,特徵,已經討論的好處和優點僅僅是示例性的。無論任何模式它們及有關它們的討論都不是用來限制保護的範圍。許多其它實施例也可以考慮。這些包括實施方案具有更少的,附加的,和/或不同的部件,步驟,特徵,好處和優點。這些也包括在其中的組件,和/或步驟的排列,和/或排序不同的實施例。The above-described components, steps, features, advantages and advantages that have been discussed are merely exemplary. Regardless of any patterns, they are not used to limit the scope of protection. Many other embodiments are also contemplated. These include embodiments having fewer, additional, and/or different components, steps, features, benefits and advantages. These are also included in the components, and/or the arrangement of steps, and/or the different embodiments.

除非另有說明,列在本說明書中所有的測量,價值,比率,位置,大小,尺寸,和其他規格,包括在以下的權利要求的規格,都是近似的描述,而不是精確的描述。它們的目的是在一個合理的範圍內具有的功能與它們有關和與什麼是慣用的技術,以它們所屬的是一致的。此外,除非另有說明,提供數值範圍的目的是包含所述下限和上限值。此外,除非另有說明,所有材料的選擇和數值只是代表性的優選實施方案;其它數值範圍和/或材料可以被使用在不同實施方案中。。All measurements, values, ratios, positions, sizes, dimensions, and other specifications included in the specification, including the specification of the claims below, are intended to be a description rather than a precise description. Their purpose is to have functions that are relevant to them and to what they are accustomed to, within a reasonable range, to be consistent with them. Further, unless otherwise stated, the numerical range is provided for the purpose of including the lower and upper limits. In addition, all material selections and values are merely representative of preferred embodiments unless otherwise indicated; other numerical ranges and/or materials may be used in various embodiments. .

保護的範圍僅由權利要求書來限定,這樣的範圍限定應旨在與權利要求中的解釋語言一致,而且要求根據本說明書的一般含義和後面的申請審查歷史相一致,並包括其所有的架構和功能的同等物的條件下,做儘可能的廣泛解釋。The scope of the protection is to be limited only by the scope of the claims, which are intended to be consistent with the language of the explanation in the claims, and are intended to be consistent with the general meaning of the specification and the subsequent application review history, and include all of its architectures. Under the conditions of the equivalent of function, do as widely explained as possible.

110‧‧‧通信經營概念
130‧‧‧預處理
010‧‧‧雲端
140‧‧‧後處理
180‧‧‧候選信封文檔
180-1‧‧‧候選信封第一子文檔
180-2‧‧‧候選信封第二子文檔
521‧‧‧第一列
522‧‧‧第二列
523‧‧‧第三列
130-1‧‧‧第一預處理
130-2‧‧‧第二預處理
140-1‧‧‧第一後處理
140-2‧‧‧第二後處理,
630‧‧‧預處理
640‧‧‧後處理
159‧‧‧智能手機
229‧‧‧分割設備,
230‧‧‧預處理
011‧‧‧手機網路
240‧‧‧後處理
241‧‧‧解分割過程,
149‧‧‧只能讀的設備
139‧‧‧筆記本
1710‧‧‧提供附加訊息的架構
1800‧‧‧母版新聞
2000‧‧‧子版新聞
1790‧‧‧用戶接收機
110‧‧‧Communication business concept
130‧‧‧Pretreatment
010‧‧‧Cloud
140‧‧‧ Post-processing
180‧‧‧candidate envelope document
180-1‧‧‧First subdocument of candidate envelope
180-2‧‧‧ Second envelope of candidate envelope
521‧‧‧first column
522‧‧‧second column
523‧‧‧ third column
130-1‧‧‧First pretreatment
130-2‧‧‧Second pretreatment
140-1‧‧‧First post treatment
140-2‧‧‧Second post-processing,
630‧‧‧Pretreatment
640‧‧‧ Post-processing
159‧‧‧Smartphone
229‧‧‧Segmentation equipment,
230‧‧‧Pretreatment
011‧‧‧Mobile network
240‧‧‧ Post-processing
241‧‧ ‧ segmentation process,
149‧‧‧Reading only equipment
139‧‧‧Note
1710‧‧‧ Architecture providing additional information
1800‧‧‧Master News
2000‧‧‧Sub-version news
1790‧‧‧User receiver

在附圖中公開了本發明示意性的一些實施例。它們並沒有闡述所有的實施例。其它實施例可另外或替代地使用。為了可以節省空間或更有效的描訴描述例子, 很多省略的細節可能是顯而易見或是不必要的。相反,一些實施例可以在沒有所有的被公開的細節的情況下實踐的。另外相同的參考編號或參考指示符會出現下不同的附圖中,它們可以指代相同或相似的部件或步驟。Some illustrative embodiments of the invention are disclosed in the drawings. They do not illustrate all of the embodiments. Other embodiments may be used additionally or alternatively. In order to save space or more efficient description examples, many of the omitted details may be obvious or unnecessary. On the contrary, some embodiments may be practiced without all of the details disclosed. In addition, the same reference numbers or reference indicators will appear in the different figures, which may refer to the same or similar components or steps.

在此申請書中的發明,可以更全面地從以下描述中可以理解,當與附圖一同閱讀申請書時,其附圖應被認為是說明性的,而不是作為申請書的限制。附圖不一定按比例繪製,而是將重點放在對本發明的原理。The invention in this application is to be understood as being understood by the description of the appended claims. The drawings are not necessarily to scale, the

圖1示出根據本發明的實施例的一幅對某一組數碼檔案的數碼信封加封框圖,其包括了透過一組2到2 波前覆用處理器把此組數碼檔案嵌入一組數碼信封中, 然侯在覆用處理器兩組輸出中選出一組透過雲端發送到目的地,並在目的地打開數碼信封和回收罩在數碼信封內的一組原數碼檔案數據。數碼信封是從對發送者及接收者都是已知的多組侯選數碼信封中所選擇的一組數碼, 也是給在源頭的發送方和在在目的地的接收方的一套數碼傳輸模式。對於一組數碼信封的加封和解加封的過程也被分別稱為加封和開封。1 shows a block diagram of a digital envelope for a certain set of digital files, including embedding the set of digital files into a set of digital images through a set of 2 to 2 wavefront overlay processors, in accordance with an embodiment of the present invention. In the envelope, a set of the two sets of outputs of the processor is selected to transmit to the destination through the cloud, and the digital envelope is opened at the destination and the original digital file data collected in the digital envelope is collected. A digital envelope is a set of numbers selected from a plurality of sets of candidate digital envelopes that are known to both the sender and the recipient. It is also a set of digital transmission modes for the sender at the source and the receiver at the destination. . The process of sealing and unsealing a set of digital envelopes is also referred to as sealing and unsealing, respectively.

圖1A示出了根據本發明的實施例的一排6組候選數碼信封。FIG. 1A illustrates a row of six sets of candidate digital envelopes in accordance with an embodiment of the present invention.

圖1B根據本發明的實施例示出了另一排5組候選數碼信封。FIG. 1B shows another row of five sets of candidate digital envelopes in accordance with an embodiment of the present invention.

圖2示出了根據本發明的一些實施例的所示的一組圖像, 它們是從美國專利申請號13/953715(PA出版物號US2014-0081989 A1)圖5D 中複製的; 同時也透過計算機類比來證明圖像偽裝的可行性。第一列的四幅圖像被輸入到一組4至4 波前覆用處理器。這幅在第一列的“跑 馬〞 圖像被選為數碼偽裝的形象。有效地,在第二列中的四幅圖像都被罩上了這幅跑馬圖。Figure 2 shows a set of images shown in accordance with some embodiments of the present invention, which are reproduced from Figure 5D of U.S. Patent Application Serial No. 13/953,715 (PA Publication No. US 2014-0081989 A1); Computer analogy to prove the feasibility of image camouflage. The four images in the first column are input to a set of 4 to 4 wavefront overlay processors. This "horse image" in the first column was chosen as the image of digital camouflage. Effectively, the four images in the second column are covered with this horse race.

圖3示出當在目的地的接收器根據本發明的一些實施例;它是 對沒法夠到原始數碼信封的用戶而言 可經由一組2對2的波前覆用器做加封/解加封過程的方框圖。它是一套類似於圖 1的方框圖,發送者透過發送覆用器兩路輸出 經由雲端送到接收器, 再透過一組2對2的波前解覆用器做還原原始數碼信封和嵌入的數碼訊息。Figure 3 shows some embodiments of the receiver at the destination according to the invention; it is a seal/solution via a set of 2 to 2 wavefront overrides for users who are unable to reach the original digital envelope. Block diagram of the sealing process. It is a block diagram similar to Figure 1. The sender sends the two outputs to the receiver via the cloud, and then restores the original digital envelope and embedded through a set of 2 to 2 wavefront de-emabovers. Digital message.

圖4示出根據本發明的一些實施例的雙加封的方框圖。4 shows a block diagram of a double seal in accordance with some embodiments of the present invention.

圖5示出根據本發明的一些實施例的解雙加封的方框圖。Figure 5 shows a block diagram of a double-encapsulation in accordance with some embodiments of the present invention.

圖6示出根據本發明的一些實施例經由高階波前覆用為一組數碼訊息嵌入一組數碼訊息內;一幅高階加封的方框圖。6 illustrates a block diagram of a high level seal that is embedded within a set of digital messages for a set of digital messages via a high order wavefront overlay, in accordance with some embodiments of the present invention.

圖7示出根據本發明的一些實施例透過高階波前解覆用從一組封后數碼流還原出嵌入的數碼訊息; 一幅高階解加封的方框圖。7 illustrates a block diagram of reconstructing an embedded digital message from a set of sealed digital streams through a high-order wavefront decoding, in accordance with some embodiments of the present invention; a high-order de-seal.

圖8示出根據本發明的一些實施例透過高階波前覆用執行嵌入數碼訊息之雙加封的方框圖。8 shows a block diagram of a double-encapsulation of an embedded digital message by high-order wavefront overlay in accordance with some embodiments of the present invention.

圖9示出根據本發明的一些實施例經由高階波前解覆用從兩個封后數碼流來還原嵌入數碼訊息之解雙加封的方框圖。9 illustrates a block diagram of de-double-encapsulation of reconstructing an embedded digital message from two subsequent digital streams via high-order wavefront decoding, in accordance with some embodiments of the present invention.

圖10示出根據本發明的一些實施方案透過一組4至4 波前覆用產生4串可用的加封數據流, 再選3串透過雲端發送的加封的方框圖。Figure 10 is a block diagram showing the generation of 4 strings of available packed data streams through a set of 4 to 4 wavefront overrides, followed by 3 strings transmitted through the cloud, in accordance with some embodiments of the present invention.

圖11示出根據本發明的一些實施例透過一組4至4 波前解覆用把從雲端下來的三串數碼流中的任兩串用來還原嵌入數碼訊息的解加封方框圖。Figure 11 illustrates a block diagram of a de-encapsulation used to restore an embedded digital message by using a set of 4 to 4 wavefront solutions to remove any two of the three strings of digital streams coming down the cloud, in accordance with some embodiments of the present invention.

圖12示出了根據本發明的一些實施例透過一組4至4 波前解覆用把從雲端下來的三串數碼流中的任兩串用來還原嵌入數碼訊息的另一解加封方框圖。Figure 12 illustrates another de-blocking block diagram for restoring an embedded digital message by using a set of 4 to 4 wavefront solutions to remove any two of the three strings of digital streams from the cloud, in accordance with some embodiments of the present invention.

圖13示出了根據本發明的一些實施例透過透過一組4至4波前解覆用把從雲端下來的三串數碼流用來還原嵌入數碼訊息的一解加封方框圖。Figure 13 illustrates a de-blocking block diagram for restoring an embedded digital message by transmitting a three-string digital stream from the cloud through a set of 4 to 4 wavefront de-splits in accordance with some embodiments of the present invention.

圖14示出了根據本發明的一些實施例中透過一組4至4波前解覆用把從雲端下來的三串數碼流用來還原嵌入數碼訊息的另一解加封方框圖。14 illustrates another block diagram of a three-string digital stream from the cloud for restoring an embedded digital message through a set of 4 to 4 wavefront de-splits in accordance with some embodiments of the present invention.

圖15示出了根據本發明的一些實施方案中透過一組2到2波前覆用 及另一組4至4波前覆用來產生只有一組透過雲端封后數碼流的雙加封方框圖。Figure 15 illustrates a dual-encapsulated block diagram for generating a set of transmitted digital envelopes through a cloud through a set of 2 to 2 wavefronts and another set of 4 to 4 wavefronts in accordance with some embodiments of the present invention.

圖16示出了根據本發明的一些實施方案中透過一組2到2波前解覆用 及另一組4至4波前解覆用而且只需用一組透過雲端封后數碼流來還原嵌入數碼訊息的解雙加封方框圖。Figure 16 illustrates the use of a set of 2 to 2 wavefront cancellations and another set of 4 to 4 wavefront cancellations and only a set of cloud-sealed digital streams through a cloud in accordance with some embodiments of the present invention. A double-blocked block diagram of embedded digital messages.

圖17A所示是按照本發明的一些實施例,應用於數字版權管理(DRM)的數碼加封框圖;透過嵌入在一件子版數碼檔案/電影畫面的獨特標識畫面,然後存儲在雲中或分別發行的子版檔案/電影畫面。,Figure 17A is a block diagram of a digital seal applied to Digital Rights Management (DRM) in accordance with some embodiments of the present invention; through a unique identification image embedded in a sub-page digital archive/movie screen, and then stored in the cloud or Sub-file/movie screens issued separately. ,

圖17B示出的是根據本發明的一些實施例對數碼檔案或雲儲存的電影圖像的解加封框圖;用來恢復嵌入在子版數碼檔案/電影畫面的獨特標識畫面或標識檔案。Figure 17B illustrates a de-blocking block diagram of a digital archive or cloud stored movie image in accordance with some embodiments of the present invention; for restoring a unique identification screen or logo file embedded in a sub-digital file/movie screen.

圖18A示出了根據本發明的一些實施例在兩本子版廣播數字檔案中經由數碼加封用不同模式嵌入的相同附加訊息,然後透過在雲端的或其他形式的廣播/再廣播的應用程式框圖。FIG. 18A illustrates an application block diagram embedded in different modes by digitally encapsulating in two sub-page broadcast digital archives, and then through a cloud or other form of broadcast/rebroadcast application block diagram, in accordance with some embodiments of the present invention. .

圖18B示出了示出了根據本發明的一些實施例在收到廣播/再廣播的兩本子版廣播數字檔案後經由數碼解加封把用不同模式嵌入的相同附加訊息恢復還原的應用程式框圖。Figure 18B shows an application block diagram showing the restoration and restoration of the same additional message embedded in different modes via digital de-seal after receiving two broadcast/re-broadcast two digital broadcast digital files in accordance with some embodiments of the present invention. .

圖19示出了示出了根據本發明的一些實施例在雲端儲存預處理後的波前覆用數據及從雲端儲存的波前覆用數據經由後處理而重組還原的原數碼數據的應用程式框圖。FIG. 19 is a diagram showing an application for storing pre-processed wavefront overlay data in the cloud and pre-processing of reconstructed original digital data from the cloud-preserved wavefront overlay data in accordance with some embodiments of the present invention. block diagram.

圖19A示出了示出了根據本發明的一些實施例在雲端儲存預處理後的波前覆用數據及從雲端儲存的波前覆用數據經由後處理而重組還原的原數碼數據的另一應用程式框圖。FIG. 19A illustrates another embodiment of original digital data recombined and restored via post-processing of pre-processed wavefront overlay data in the cloud and pre-filtered overlay data stored from the cloud in accordance with some embodiments of the present invention. Application block diagram.

圖19B示出了示出了根據本發明的一些實施例在雲端儲存預處理後的波前覆用數據及從雲端儲存的波前覆用數據經由後處理而重組還原的原數碼數據的另一應用程式框圖。FIG. 19B illustrates another embodiment of the original digital data recombined and restored by post-processing in the cloud storage pre-processed wavefront overlay data and cloudfront stored overlay data stored in the cloud, in accordance with some embodiments of the present invention. Application block diagram.

圖19C示出了示出了根據本發明的一些實施例在雲端儲存預處理後的波前覆用數據及從雲端儲存的波前覆用數據經由後處理而重組還原的原數碼數據的另一應用程式框圖。FIG. 19C illustrates another embodiment of the original digital data recombined and restored via post-processing of the wavefront overlay data stored in the cloud and the wavefront overlay data stored from the cloud in accordance with some embodiments of the present invention. Application block diagram.

圖20示出了示出了根據本發明的一些實施例利用某一用戶的一設備在雲端儲存加封原訊息數碼後的波前覆用數據及從雲端儲存的波前覆用數據經由該用戶的另一設備的後處理而重組還原的原訊息數數據的一應用程式框圖。FIG. 20 is a diagram showing the wavefront overlay data after the original message digit is stored in the cloud by a device of a certain user and the wavefront overlay data stored from the cloud via the user according to some embodiments of the present invention. An application block diagram of the reprocessing of the original message number data by post-processing of another device.

圖20A示出了示出了根據本發明的一些實施例利用某一用戶的一設備在雲端儲存加封原訊息數碼後的波前覆用數據及從雲端儲存的波前覆用數據經由該用戶的另一設備的後處理而重組還原的原訊息數數據的另一應用程式框圖。FIG. 20A is a diagram showing the wavefront overlay data after the original message digit is stored in the cloud by a device of a certain user and the wavefront overlay data stored from the cloud via the user according to some embodiments of the present invention. Another application block diagram of the reprocessing of the original message number data by post-processing of another device.

圖20B示出了示出了根據本發明的一些實施例利用某一用戶的一手持設備在雲端儲存加封原訊息數碼後的波前覆用數據及從雲端儲存的波前覆用數據經由該用戶的另一手持設備的後處理而重組還原的原訊息數數據的一應用程式框圖。FIG. 20B illustrates a wavefront overlay data and a wavefront overlay data stored from the cloud stored by the user using a handheld device of a certain user in the cloud according to some embodiments of the present invention. An application block diagram of the reprocessing of the original message number data of another handheld device.

圖20C示出了示出了根據本發明的一些實施例利用某一用戶的一手持設備在雲端儲存加封原訊息數碼後的波前覆用數據及從雲端儲存的波前覆用數據經由該用戶的另一手持設備的後處理而重組還原的原訊息數數據的另一應用程式框圖。FIG. 20C illustrates a wavefront overlay data and a wavefront overlay data stored from the cloud stored by the user using a handheld device of a certain user in the cloud according to some embodiments of the present invention. Another application block diagram of the reprocessing of the original message number data of another handheld device.

110‧‧‧通信經營概念 110‧‧‧Communication business concept

130‧‧‧預處理 130‧‧‧Pretreatment

010‧‧‧IP雲端 010‧‧‧IP cloud

140‧‧‧後處理 140‧‧‧ Post-processing

180‧‧‧候選信封文檔 180‧‧‧candidate envelope document

Claims (19)

一組在私人設備上文檔輿一組在目的地上文檔之間的一套數碼數據傳輸和存儲系統;包括︰ 一組在私人設備上文檔; 一組能執行從多路輸入到多路輸出變換的預處理器,           其中所述多個輸入端,其包括的在該私人設備文檔中的第一條輸入流,和作為數碼信封文件的第二條數據流;         其中所述預處理器的第一輸出端包括一條有加封後數碼數據流,及 一條傳輸信道;該信道被配置為連接所述預處理器的第一輸出端和所述的目的地。A set of digital data transmission and storage systems on a private device, a set of documents between destinations; including: a set of documents on a private device; a set of functions capable of performing multiple inputs to multiple output transforms a preprocessor, wherein the plurality of inputs include a first input stream in the private device document, and a second data stream as a digital envelope file; wherein the first output of the preprocessor The terminal includes an encrypted digital data stream and a transport channel configured to connect the first output of the pre-processor to the destination. 如申請專利范圍第1項所述之系統,其中所述加封後數碼數據更包括一組由第一條及第二條輸入流組成的加權和並且該數碼形式的加權和輿所述第二條輸入流對人體音頻感官而言基本上會有完全相同的音頻特點。The system of claim 1, wherein the sealed digital data further comprises a set of weighted sums of the first and second input streams and a weighted sum of the digital forms. The input stream will basically have exactly the same audio characteristics for human audio senses. 如申請專利范圍第1項所述之系統,所述的數碼信封對所有預期的閱讀設備而言都是已知的。The digital envelope described is known to all intended reading devices as in the system of claim 1. 如申請專利范圍第1項所述之系統,系配置在一台可移動私人設備或一台個人電腦上。The system described in claim 1 is configured on a portable private device or a personal computer. 如申請專利范圍第1項所述之系統,系配置在一台可移動私人設備或一台個人電腦 輿一分布式存儲系統之間。The system described in claim 1 is disposed between a portable private device or a personal computer and a distributed storage system. 如申請專利范圍第5項所述之系統,其中該存儲系統包括了在雲端的存儲系統。The system of claim 5, wherein the storage system comprises a storage system in the cloud. 如申請專利范圍第1項所述之系統,所述的預處理器更被配置為有選擇一件加封後數碼文檔來顯示的功能。The system of claim 1, wherein the preprocessor is further configured to have a function of selecting a sealed digital document for display. 如申請專利范圍第1項所述之系統,所述的在預處理器中的轉換更包括了對輸入數碼文檔中的一件做優惠加權的功能對所有多條數碼輸出的傳感外觀,對人體圖像,視頻或音頻感官而言,輿所述該件優惠加權輸入數碼文檔的傳感特點基本上會完全相同。The system of claim 1, wherein the conversion in the preprocessor further comprises a function of preferentially weighting one of the input digital documents to sense the appearance of all of the plurality of digital outputs, In terms of human body image, video or audio sense, the sensing characteristics of the weighted input digital document described above are basically the same. 如申請專利范圍第1項所述之系統,所述的在預處理器中的轉換更包括了利用正交矩陣轉換的波前覆用。As described in the system of claim 1, the conversion in the preprocessor further includes wavefront overtaking using orthogonal matrix conversion. 如申請專利范圍第9項所述之系統,所述的轉換更包括了傅立葉轉換。The system of claim 9 further includes a Fourier transform. 如申請專利范圍第9項所述之系統,所述的轉換更包括了海大媽轉換。As described in the system of claim 9, the conversion further includes a sea aunt conversion. 如申請專利范圍第1項所述之系統,在預處理器中所述的轉換更包括了利用非正交滿序矩陣轉換的波前覆用。As described in the system of claim 1, the conversion described in the preprocessor further includes wavefront override using non-orthogonal full-matrix conversion. 如申請專利范圍第1項所述之系統,在所述的預處理器中的所述的多路輸入更配置為可連接到一件已知的共用數碼文件但對不同輸入端口加上不一樣的時延遲。The system of claim 1, wherein the multiple inputs in the preprocessor are configured to be connectable to a known shared digital file but are different for different input ports. Time delay. 如申請專利范圍第1項所述之系統,把所述的預處理器中的所述的多路輸出中的一路接地。A system as claimed in claim 1, wherein one of said plurality of outputs in said preprocessor is grounded. 如申請專利范圍第1項所述之系統,在所述的預處理器中的所述的多路輸入中更包括一組有驗証功能的數據集。The system of claim 1, wherein the plurality of inputs in the preprocessor further comprise a set of data sets having verification functions. 一組在雲端上的儲存文檔輿一組在接受目的地上文檔之間的一套數碼數據文件傳輸和檢索系統;包括︰ 一組儲存在該雲端文檔中的加封後數碼文件; 一組在該接受目的地上的後處理器被配置成能執行一套從多路輸入到多路輸出的變換,        其中所述多條輸入端,包括了連接到儲存的加封後數碼文件的第一條輸入流;        其中所述後處理器的第一輸出端,包括一條重組恢複後的原信息數碼的第一條輸出數據流,及 一條傳輸信道;該信道被配置為連接所述後處理器的第一輸出端和所述雲端上的儲存文檔。A set of stored documents on the cloud, a set of digital data file transfer and retrieval systems between documents on the receiving destination; including: a set of sealed digital files stored in the cloud document; A post processor on the destination is configured to perform a set of transformations from multiple inputs to multiple outputs, wherein the plurality of inputs includes a first input stream coupled to the stored sealed digital file; The first output of the post-processor includes a first output data stream of the reconstructed original information digit, and a transport channel; the channel is configured to connect to the first output of the post-processor and Store the document on the cloud. 如申請專利范圍第16項所述之系統,其中所述重組恢複後的原信息數碼更包括了對第一及第二輸入數碼文檔的加權和而且該第一輸入的數碼文件格式傳感外觀,對人體音頻感官而言,輿所述該第二輸入數碼文件的傳感特點基本上會完全相同。The system of claim 16, wherein the reconstituted restored original information number further comprises a weighted sum of the first and second input digital documents and the first input digital file format sensing appearance, For human audio senses, the sensing characteristics of the second input digital file are substantially identical. 如申請專利范圍第16項所述之系統,其中所述多路輸入更包括了用作數碼信封的第二輸入數碼文件。The system of claim 16, wherein the multiplex input further comprises a second input digital file for use as a digital envelope. 如申請專利范圍第16項所述之系統,系配置在一台可移動私人設備或一台個人電腦上。The system described in claim 16 is configured on a portable private device or a personal computer.
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