This invention relates to a book and a method for indicating an open page of a book.
Despite the increase use of electronic books in various form of electronic devices, physical books with physical leaves remain popular. Physical books are the recommended reading media especially for the young generation. Instead of replacing physical books by electronic books, new methods and apparatus that assist in advancing technological needs and industrial applications in integrating electronic devices with the physical books are desirable.
One example embodiment is a book with a plurality of pages, a plurality of magnets, and a sensor. Each of the plurality of magnets is disposed at a pre-determined location of each of at least two of the plurality of pages and generates a magnetic field. The plurality of the magnets generate a combined magnetic field strength, which is variable depending on positions of the pages on which the magnets are disposed. The sensor senses the combined magnetic field strength and generates a varying signal based on a varying of the combined magnetic field strength when at least one page is moved. The varying signal indicates a position of at least one page in the book.
Another example embodiment includes a method that indicates a page of a book that is currently open, in which the book includes a plurality of pages. The method includes producing, by a plurality of magnets with each magnet disposed at each of at least two of the plurality of pages, a combined magnetic field strength; sensing, by a sensor in the book, the combined magnetic field strength; generating, by the sensor, a varying signal based on a varying of the combined magnetic field strength when at least one page is moved; and indicating, based on the varying signal, the page of the book that is currently open. The combined magnetic field strength is variable depending on positions of the pages on which the magnets are disposed.
In yet another example embodiment, a book is provided containing a plurality of pages, a first sensor magnet disposed at a back cover page of the book, a plurality of magnets and a first sensor in the book. Each magnet of the plurality of magnets is disposed at the plurality of pages and generates a magnetic field. One or more of the magnets generate a first combined magnetic field strength that acts on the first sensor magnet. The first combined magnetic field strength is variable depending on positions of the pages on which the magnets are disposed. The first sensor measures the first combined magnetic field strength and generates a first signal based on the first combined magnetic field strength. The first signal determines a position of at least one page in the book
Other example embodiments are discussed herein.
As used herein and in the claims, “comprising” means including the following elements but not excluding others.
Example embodiments relate to apparatus and methods that indicates a page of a book that is currently open.
Example embodiments include a physical book coupled with one or more electronic devices to produce light, motion, sound, image, video, or any of their combinations when a page of the book is moved or opened. Thus, the example embodiments provide possibility for content providers to implement value added features. The value added features may not necessarily be produced at the same time when the page is opened. The value added features are, for example, auto playback of animal sounds of the wild life mentioned in a particular page; a mini game to solve the question printed on a particular physical page; auto retrieve related animations video for user to manually playback that supplements the book content after a user finished reading the page; multilingual translated voice over for the current page content etc.
Conventional or existing physical books that couple electronic devices are limited in applications. Readers are required to make transient contacts or engagements with pre-determined areas in a page of the books in order to create a signal. E.g. point to a cartoon or a designated area of the page. However, these conventional books are limited to a group of users who have the ability to comprehend and recognize the pre-determined areas in the page of the books. Example embodiments of the present invention include a plurality of magnets in pages of a book to generate a varying signal based on a varying of a combined magnetic field strength when a page is moved. In this way, the book has the ability to sense what the user is doing and provide predetermined responses according to the publisher or producer's intention without necessarily requiring any additional trigger from the user other than the turning of the page. The applications of the example embodiments are not limited to certain age groups and education sectors, etc.
Example embodiments solve the above-stated problems or difficulties by providing new methods and apparatus that integrate electronic devices with the physical books in a simple way to provide enhanced content and interactive user experience.
In another example embodiment, the sensor 108 is a pressure sensor that includes a sensor magnet embedded at page 116. By way of example, a load (not shown but indicated by arrow 120) is provided in the book 100 at a position juxtapose the first sensor magnet. The sensor 108 measures the combined magnetic field strength that acts on the sensor magnet against a preloading force produced from the load.
In another example embodiment, the book 100 is connected with a processor (indicated by arrow 107) and a wired or a wireless power supply (not shown). The power supply provides electricity to the sensor 108 and the processor. By way of example, the power supply is a battery. The processor converts the varying signal into light, motion, sound, image, video or their combinations. In yet another example embodiment, the book 100 does not include a power supply and the sensor 108 operates without a power supply.
In yet another embodiment, computing devices or built-in electronics are embedded in the book 100 or remotely connected to the book 100. When a currently open page of the book 100 being viewed by a reader is detected or determined based on the varying of the combined magnetic field strength, the book 100 allows communications via one or more networks. Furthermore, usage or user habit on reading the book can be collected. The network can include one or more of a wired network or wireless network, such as internet, cellular network, etc.
By way of example, the book 200 includes a second sensor magnet (not shown but may be at, for example, position indicated by the arrow 230) attached to the outer side of the front cover page of the book. One or more of the magnets 201, 202, 203, 204, 206 generate a second combined magnetic field strength that acts on the second sensor magnet. The second sensor measures the second combined magnetic field strength that acts on the second sensor magnet and generates a second signal based on the second combined magnetic field strength. The second combined magnetic field strength is variable depending on positions of the pages on which the magnets are disposed. A difference between the first signal and the second signal indicates the position of at least one page in the book. The difference can be expressed, calculated or generated as a ratio, percentage, etc.
The methods in accordance with example embodiments are provided as examples, and examples from one method should not be construed to limit examples from another method. Further, methods discussed within different figures can be added to or exchanged with methods in other figures. Further yet, specific numerical data values (such as specific quantities, numbers, categories, etc.) or other specific information should be interpreted as illustrative for discussing example embodiments. Such specific information is not provided to limit example embodiments. For example, the sensor can be disposed in one of the plurality of pages and not necessarily be disposed in any of the cover pages. Also, the sensor is not necessarily to be stacked by one or more of the plurality of magnets, but is put within a close proximity that can successfully sense a varying of magnetic field strength. Also, the sensor can be any sensor that is able to sense a varying of magnetic field strength or any device that detects changes of magnetic field strength and send the information to other electronics. In addition, the plurality of pages can be composed of the plurality of magnets such that each magnet forms as a page in the book. Furthermore, the magnets disposed at each of the plurality of pages can be done by attachment, adhesion, embedment, affixing or any means that place the magnets at the pre-determined locations. Also, by way of example, the sensor, the first sensor or the second sensor in the example embodiments can be a pressure sensor, a magnetoresistive sensor, a magnetometer, a Hall effect sensor or a magnetic field sensor that include but is not limited to a passive and an active sensor.
As used herein, “binding side” means an edge of a book that bound or assemble a stack of individual pages of the book.
As used herein, “coaxial” refers to having a common axis or coincident axis. For example, when two magnets are stacked “coaxially”, they do not necessarily be completely overlap each other but one partially covers the another.
As used herein, “front cover page” and “back cover page” refer to two opposing sides of a book and are interchangeable. For example, the “front cover page” in an example embodiment does not necessarily mean a beginning of the book, but refer to an opposing side of the “back cover page”.
As used herein, “magnet” refers to any magnetic materials that include but are not limited to electromagnets and permanent magnets.
As used herein, “indicates”, “indication” or “indicating” does not necessarily refer to the user, it can refer to a processor that makes a conversion of the signal.
As used herein, “sensor magnet” can be a magnet, a ferromagnetic material or a ferrimagnetic material. Examples of ferromagnetic materials are cobalt, iron, iron(III) oxide, iron(II,III) oxide, bismuth, nickel, yttrium iron garnet, chromium(IV) oxide, gadolinium, terbium, dysprosium, europium oxide, MnAs, MnSb, MgOFe2O3, CuOFe2O3, or NiOFe2O3. An example of a ferrimagnetic material is magnetite.
Number | Name | Date | Kind |
---|---|---|---|
5707240 | Haas | Jan 1998 | A |
7290700 | Song | Nov 2007 | B2 |
20050200116 | Chiu | Sep 2005 | A1 |
20080268416 | Wallace | Oct 2008 | A1 |
20100167258 | Ravizza | Jul 2010 | A1 |
Number | Date | Country |
---|---|---|
1595420 | Mar 2005 | CN |
201918043 | Aug 2011 | CN |
105023470 | Nov 2015 | CN |
204955798 | Jan 2016 | CN |
Number | Date | Country | |
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20190322116 A1 | Oct 2019 | US |