NL1026744C1 - Device method and system for receiving and sending information using different communication networks. - Google Patents

Description

TITLE Device method and system for receiving and sending information using different communication networks.

The invention relates to a device, method and system for receiving and sending information using different communication networks. The device is particularly suitable for use in a T-DAB or DVB-T transmission network combined with a GPRS communication network. DAB (Digital Audio Broadcasting) and DVB (Digital Video Broadcasting) transmission networks and communication technology for digital audio and video transmission using a digital format have been developed to replace the existing now obsolete radio and television analogue transmission technology such as e.g. FM (Frequency Modulation) and VHF / UHF television signals. In Europe, the "Eureka 147 DAB" protocol has been agreed for DAB based on standard ETSI EN 300 401 V1.3.3. Eureka DAB has been developed for good "mobile" reception and can be applied to frequencies between 30 MHz to 3 GHz. Each DAB transmission frequency with a bandwidth of 1,536 MHz, or DAB ensemble or DAB block, can now contain a multiplex of audio and / or multimedia services depending on the desired and chosen configuration. The gross bit rate of a multiplex is approximately 2.3 Mbits / s but due to redundancy, error correction and other overhead to improve the reception a net data stream of approximately 1.7 Mbits / s is available. The transmission frame can be flexibly divided into segments such as video, data streams or audio transmitters, depending on the need, for example in six 192 Kbits / s digital audio data streams or in ten 100 Kbits / s multimedia data streams or any other desired distribution or combination.

25 This TM-I technology for DAB transmitters below 375 MHz is very suitable for an SFN (single-frequency network, common frequency network or one frequency network). In particular because interference problems such as intersymbol interference in transition areas between the different transmitters are also suppressed by the added robust redundancy and error correction 30 for a good "mobile" or moving reception.

For higher transmission frequencies such as the L-band, 2 other transmission modes are defined, TM-II and TM-IV. TM-II and TM-IV in particular are suitable for use with 1026744-2 for the so-called L-band transmitters whose frequencies are between 1.452 and 1.402 GHz. The transmission signal is split into 384 (mode II) 768 (mode IV) carriers in this transmission mode. Due to the higher frequency of the carrier, the maximum mutual transmitter distance is only about 25 km Mode II and about 50 km mode IV, while for VHF-III (band-III) frequencies (174-230 MHz) this maximum transmitter distance is approximately 100 kilometers . As a result, the band III frequencies are often used for national DAB SFN broadcasting networks and L-band frequencies are used on a very limited scale for regional SFN applications or for local one (MFN) transmitter applications.

The device according to the invention focuses in particular on transmission networks formed from transmitters placed on the earth; the so-called Terrestrial or T-DAB networks to distinguish with e.g. cable transmission networks or satellite transmission networks and in particular on mobile telephone networks such as the GPRS. GPRS has been developed as an intermediate step to UMTS. GPRS has the capabilities of the first generation of mobile telephony such as GSM with added circuit switched voice connection and packet switched data functionality.

The invention therefore has for its object a device for receiving and sending information for a user with the aid of different communication networks, the device comprising at least: a central processing unit or CPU module, provided with a CPU and working memory for controlling the remaining modules ; a T-DAB Band III receiver; a T-25 DAB L-band receiver; a storage medium and a GPRS mobile telephony module.

The device is preferably provided with a user interface, an interface module for data communication with devices outside the communication device.

The invention also relates to a method for receiving and sending information with a communication device, comprising the following steps: 1026744-3 receiving digital data with T-DAB band III receiver, receiving digital data with T-DAB DAB L-band receiver, processing of the digital data by the CPU module using one or more software programs, sending the digital data to one or more modules selected by the user.

The modules are preferably selected from: GPRS module, storage module, user interface, interface module, loudspeaker, microphone, computer or a cradle and the software programs are selected from: DAB application, Internet application, E-mail application, Route planner application, Alert application.

In particular, the method also comprises: splitting the digital data in the T-DAB receiver into an audio data stream and an information data stream, and preferably also: processing the information stream such as the FIC information by one or more in the CPU module running software applications to present alarm messages or paging calls directly to the user.

In particular, the method also comprises: processing the "meta tags" in the information stream such as the FIC; storage of information whose 'meta tags' correspond to the profile set by the user (Alter ego), and preferably also: saving a selection of Internet pages (Web carousel) on the storage medium for direct (virtual) surfing by the user .

25

The invention also relates to a communication system for sending and receiving information comprising: a T-DAB band-ll network, a T-DAB L-band network, a GPRS network, a central server, a communication device, 1026744 - 4 wherein the DAB networks and the GPRS network are centrally controlled from a central server for receiving and sending information to the communication device.

The central server is preferably provided with a decision model which, on the basis of parameters, determines via which network the information is sent to the communicating device.

In particular, if the amount of information requested does not exceed the value of a first parameter (for example 500 kB), the information is sent via the GPRS network.

Preferably, when the amount of requested information is between a first parameter (e.g. 500 kB) and a second parameter (e.g. 1 MB), the information is sent via a DAB network, if sufficient space is present on the relevant multiplex, otherwise the information is sent via the GPRS network.

In particular, when the amount of information requested exceeds the value of a second parameter (e.g., 500 kB), the information is sent via a DAB network.

The invention will now be further elucidated with reference to the drawing.

Fig. 1 shows a block diagram of the communication device according to the invention, Fig. 2 shows a block diagram of the communication system according to the invention.

In Fig. 1, in a block diagram, the communication device 7 according to the invention is shown with T-DAB Band-III receiving module 1A and T-DAB L-Band receiving module 1B. The receivers 1A and 1B receive digital data such as a T-DAB block or multiplex H with, for example, five digital audio channels and two data channels. In the receivers 1A and 1B this digital information is separated from each other and the selected information is sent to the CPU module 3. For clarity, data information B and audio information A may be shown with a separate arrow; in reality, these data streams are included in the digital transmission frame or "symbol" within the Eureka-DAB protocol and are only separated again in the different data streams in the receiver 1A or 1B. Sending information between the DAB receivers 1A and 1B will usually take place over a communication bus, but if desired use can also be made of several communication buses. The central processing unit 3 or CPU module includes a quantity of working memory and communication buses to the other modules of the communication device 7. A storage medium 4 is connected to the CPU module 3 by means of a suitable known communication bus. This storage medium 4 can be a hard disk 10 but also a bank of memory chips. The storage medium 4 stores the programs for the applications that will be executed on the central processing unit. The CPU module 3 is also connected via connection E to user interface 5, which is for example formed by an LCD screen with a touch screen. Other known user interfaces can also be used as a keyboard, navigation keys in combination with a display. Using the user interface, commands can be given to the various modules via the CPU module 3.

Connected to the CPU module 3 is also via connection C the GPRS module 2 which takes care of the communication with the GPRS mobile telephony. The communication device 7 is furthermore provided with an interface module 6 which transmits digital (audio) data streams or data packets e.g. transmits from the CPU module 3 or from the GPRS 2 to a device outside the communication device 7 such as, for example, an analog audio loudspeaker 8 or another data receiving device such as a computer 10 or a cradle 11, which is provided with a power supply connection which ensures transmission. of the data streams. The interface module 6 also takes care of reading in digital data streams from, for example, a microphone 9 and transmits the data to, for example, GPRS 2 or CPU module 3. Optionally, the A / D and D / A converters can be part of the interface module 6 when an analog audio signal is received from the microphone 9.

The entire communication device can be operated by the user by using. the user interface. Known applications such as making a telephone call and sending an SMS can be carried out with the GPRS module 2. Via the user interface 5, the required commands are sent to the GPRS module 2 via the CPU module 3 for this purpose. The GPRS module 2 sends information via the CPU module 3 back to the user interface such as known status information about telephone calls or sent or received SMS messages.

The central processing unit or CPU module 3 is furthermore connected to storage medium 4. On the storage medium 4 the (software) applications are stored which are executed on the CPU module to perform certain tasks or assignments. The storage medium 4 can also be used to store received data such as audio data from a T-DAB receiver 1A, 1B or audio data from the GPRS module 2. Also received multimedia data such as for example data or pages from the Internet can be stored on the storage medium 4.

The central processing unit on CPU module 3 is multitasking so that multiple programs or applications can be executed simultaneously. These multitasking functions can be performed and managed by an operating system such as Windows CE, Symbian or Linux.

Software applications or applications that can be executed on the central processing unit or CPU module 3 are: DAB application such as for example a media player which takes care of controlling and tuning the T-DAB receivers and which forwards the digital audio data streams to, for example, the interface module 6 for listening by a user or to the storage medium 4. It is also possible to simultaneously send audio data streams to the interface module 6 and to send one or more audio data streams to the storage medium 4

Internet application such as an Internet browser that can request and process Internet information or content via T-DAB receivers 1A or 1B

and / or GPRS module 2 and can store this information on the storage medium 4 or display it on user interface 5.

1026744-7 E-mail application for handling all send and receive tasks via the GPRS module 2 and display tasks via the user interface 5. E-mail reception and processing originating from the Internet can also be processed with this application if desired.

Route planner application for displaying route information for example during a car trip. Optionally, via the GPRS module 2 or the T-DAB receivers 1A, 1B, up-to-date data or information about the traffic situation 10 can be provided, for example, via the TMC (traffic management channel) of the FIC (Fast

Information Channel) of each DAB multiplex to the user are shown via the user interface 5 and / or interface module 6.

Alarm application for receiving and processing 15 alarm messages such as via the EWC (Emergency Warning

Channel) of the FIC of a DAB multiplex which application also brings the alarm message to the attention of the user via the user interface 5 and / or interface module 6.

Paging or call application for receiving and processing calls such as for example via the Pager Channel of the FIC of a DAB multiplex and to inform the user of the call information.

To illustrate the operation of the device, the operation of the web carousel is now described as an example. A web carousel is broadcast via the national (Band-lll) and local (L-Band) DAB Allotment (s) or multiplexes. The web carousel contains a selection of Internet pages, for example a number of Internet pages with local and / or national information. The Web carousel data 30 is received by a T-DAB receiver 1A, 1B and sent via B to the CPU module 3. Hence the data goes via E to the storage medium 4 where it is stored. The total content of the Webcarrousel is stored in one go on the first connection 1026744-8 with the national multiplex. If all data has been stored, the data will be stored on the storage medium 4 until an update of the relevant information takes place. The selection of the Webcarrousel data of the L-Band, for example, takes place manually and can be adjusted by the user to his needs at any time. The processing route is the same as that of the national Web carousel. To retrieve the desired information, the web browser or Internet browser application is booted up via the touch screen of the user interface. The information is requested via G, the CPU module 3, E and from the storage medium 4. From the storage medium 4, via E, the CPU module 3 and 6, the information ends up at the user interface 5 where it is displayed. In this way, virtual live surfing on the Internet, in other words it is a form of walled Internet. It is also possible to surf the live Internet via the T-DAB receivers. The Internet surf action can be started from the national or local web carousel (the requested page is not in the web carousel) or by entering an internet address in the user interface. Via G the command goes to the CPU module 3. The CPU module 3 sends a question or request via E to the storage medium 4. If the requested page is not present on the storage medium 4, the CPU module 3 asks the question via C and the GPRS 20 channel 2 on the WWW. The information is received via the GPRS module 2 and forwarded via C to the CPU module 3 which displays the information on the screen 5 via G.

If the requested information contains a large amount of bytes, then software on the ISP side (in negotiation with the DAB multiplex software) decides to send the information via the DAB channel, preferably a local L-band multiplex.

As an example for handling the alarm information, the methods for processing traffic information and calamity information are described here. In the CPU module 3, a suitable software application such as PITA (Personal Intelligent Travel Assistant) or navigator software or route planner is firstly loaded. Via the DAB receivers 1A, 1B it becomes TMC

1026744-9 (Traffic Management Channel). The TMC information ends up in the CPU module 3 via B. In the CPU module 3 the information is added to the route planner software or application. The adjusted information is shown on the screen via G. The DAB receivers 1A, 1B continuously receive the EWC (Emergency Warning Channel). The moment a calamity occurs, this is reported to the DAB receiver via the EWC. The receiver automatically switches to the emergency message. The i DAB receiver 1A, 1B receives a calamity message via the EWC. The DAB receiver 1A.1B is forced to switch to the channel where the emergency information is transmitted. The calamity information is transported via A (audio) and B (data) to the CPU module. The data information is transported to the screen via G, the active application is immediately interrupted and the calamity information appears directly on the screen. From the CPU module, the audio information is sent directly to the interface module 15 such as a bluetooth mudule 6 via F. The active audio stream is interrupted and the emergency information is audible. If the communication device is in monitor mode, the device is switched on and the sound starts to produce and vibrate. All calamity information, both audio and data and the user's response to this is stored from the CPU module via E to the storage medium 4.

The handling of Paging or call information by the communication device takes place in the following manner. The Paging software program is activated by means of an activation command via the touch screen of the user interface. The command goes via G to the CPU module 3 from where the command loads the paging program via E and starts from the storage medium 4. Via E, the CPU module 3 and G the information ends up at the touch screen of the user interface 5, where the information is shown to the user. The Paging software program is now mandatory, that is, all programs running on the communication device are interrupted and the user is immediately informed that a call message has been received.

When the communication device is in standby mode, the 1026744 communication device is activated and the sound starts to produce and vibrate. The page call is received via the DAB receiver 1A, 1B. The information goes via B to the CPU module 3. From there it is transported via E to the storage medium 4, where it is stored. Simultaneously 5 the information is sent via G that a page message has been received. The communication device starts to vibrate and produce sound simultaneously. The information is requested via the touch screen 5 and a menu structure on it. Via G, the request request goes to the CPU module 3. Hence the request request goes to the storage medium 4. The requested information can consist of data (text, images and / or video) and / or audio. The data and / or audio goes via E to the storage medium 4, from there the data is transported via G to the screen of the user interface 5 on which the information is shown to the user. The audio signal is transported via F to the interface module 6 such as a Bluetooth module.

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The communication device can also be provided with functionality by means of special application software (Alter Ego) to monitor and analyze usage behavior. This user profile can be further adjusted by the user to his wishes. With the help of the user profile, Alter ego filters meaningful information from the data streams for the user by comparing the “meta data” that is sent with the content with the preferences indicated in the user profile. The profile of the user is stored locally by the Alter 25 ego, for example on the storage medium 4 and can be switched on or off by the user. This allows direct marketing to be applied without violating user privacy. If desired, payment software, so payment functionality, can also be added to the communication device. The Alter ego software, when enabled by the user, receives and analyzes the Fast Information Channel (FIC) of a DAB ensemble 24 hours a day. The Alter ego software is executed on the CPU module 3 and receives the FIC information 24 hours a day. The FIC information is received 1026744-11 by one or more DAB receivers 1A.1B and via B this information ends up with the CPU module 3. The Alter ego software assesses the information for relevance, based on a decision model set by the user and assesses whether the information is applicable or not. If the information applies, the information is stored via E on the storage medium 4.

Fig. 2 shows an overview of the communication system with communicating device 7, T-DAB band-11 network 12, T-DAB L-band network 13 and GPRS network 14. This example shows the possibility of accessing from the central server 15 to control how the information desired by the user is sent to the communication device 7.

When the user requests an Internet page on his communicating device 7, the query is ultimately processed by a central server 15. In this server it is also decided via which network the requested information such as an internet page is sent to the communication device 7 of the user. The Internet page can for instance be requested from Internet service provider (ISP) 16. Preferably, the server 15 is provided with a decision model application, which decides on the basis of set parameters via which network the requested content is sent to the communication device 7. sent. For example, it can be set that above 500 Kbytes the information is sent via a DAB network if there is sufficient space in the transmission frame of the relevant DAB multiplex, otherwise the information is sent via the GPRS network to the communication device. Above 1 Mbyte, the information is forcibly sent via a DAB network, in other words, space must be made in the DAB Ensemble. Often a local L-band multiplex will then be used to send the requested data, but if desired the server can decide to use a national band-lll ensemble for this.

The same method can also be used for interactive radio in which the user takes part, for example, in an SMS game or in a survey. The survey form can be sent with digital data from the DAB multiplex. If the user wishes to complete the survey, he can therefore use the user interface 1026744 = 12. When the survey is completed, the information is sent via the GPRS module to the GPRS network 14, which then forwards the information to the central seiver 15. When the result or an intermediate state of the survey is known, the central server 15, 5 possibly using the decision model, can send this information to the user via the most optimal route and network.

CONCLUSIONS

1023744-

Claims (15)

Device (7) for receiving and sending information for a user with the aid of communication networks, the device (7) comprising at least the following modules: a central processing unit or CPU. module (3) provided with a CPU and a working memory for controlling the remaining modules; a T-DAB Band III receiver (1A); a T-DAB L-band receiver (1B); a storage medium (4) and a GPRS mobile telephony module (2). Communication device (7) according to claim 1, characterized in that the device is also provided with a user interface (5). Communication device (7) according to one of Claims 1 or 2, characterized in that the device is also provided with an interface module 6 for data communication with devices (8, 9, 10, 11) outside the communication device (7) ). Method for receiving and sending information with a communication device (7) according to one of claims 1 to 3, comprising the following steps: receiving digital data with T-DAB band-III receiver (1A), receiving digital data with T-DAB L-band receiver (1B), processing of the digital data by the CPU module (3) using one or more software programs, sending the digital data to one or more modules selected by the user (2) , 4, 5, 6, 8, 9, 10, 11) 1026744- Method according to claim 4, characterized in that the software programs are selected from: DAB application, Internet application, E-mail application, Route planner application, Alarmemgs application. 5 Method according to one of claims 4 to 5, characterized in that the modules are selected from: GPRS module (2), storage module (4), user interface (5), interface module (6), loudspeaker (8), microphone (9), computer (10) or a cradle (11). 10 Method according to one of claims 4 to 6, characterized in that the method also comprises: splitting the digital data in the T-DAB receiver (1A, 1B) into an audio data stream (A) and an information data stream (B ). A method according to any one of claims 4-7, characterized in that the method also comprises: processing the information stream such as the FIC information by one or more software applications running in the CPU module (3) for alarm messages or paging calls directly to the user. 20 A method according to any one of claims 4-8, characterized in that the method also comprises: processing the "message tags" in the information stream such as the FIC; storage of information whose "meta tags" correspond to the profile set by the user (Alter ego). 25 A method according to any one of claims 4-9, characterized in that the method also comprises: storing a selection of Internet pages (Web carousel) on the storage medium (4) for direct (virtual) surfing by the user. 30 L A communication system for sending and receiving information comprising: 1026744 - a T-DAB band-11 network (12), a T-DAB L-band network (13), a GPRS network (14), a central server (15) ), A communication device (7) according to claims 1-3, wherein the DAB networks (12, 13) and the GPRS network (14) are centrally controlled from a central server (15) for receiving and sending information to the communication device (7). 12. A communication system according to claim 11, characterized in that the central server (15) is provided with a decision model which, on the basis of parameters, determines via which network the information is sent to the communicating device (7). 13. A communication system according to claim 12, characterized in that when the amount of information requested does not exceed the value of a first parameter (e.g. 500 kB), the information is sent via the GPRS network. A communication system according to any one of claims 12 to 13, characterized in that when the amount of requested information is between a first parameter (e.g. 500 kB) and a second parameter (e.g. 1 MB) the information is sent via a DAB network if there is sufficient space on the relevant multiplex, otherwise the information is transmitted through it 25 GPRS network sent. A communication system according to any one of claims 12-14, characterized in that when the amount of requested information exceeds the value of a second parameter (e.g. 500 kB), the information via a 30 DAB network is being sent. 1028744-