GB2445659A - Navigation device including audio and/or visual traffic information - Google Patents

Abstract

A navigation device displays a route superimposed on a road map, together with one or more symbols each indicating a location for which audio or visual traffic information exists, each symbol being selectable to play back the audio or visual information. Visual traffic information can be from a fixed traffic camera; a driver can hence rapidly view a video feed or still image from a traffic camera to allow him to assess the traffic conditions.

Description

A METHOD OF DISPLAYING AUDIO OR VISUAL TRAFFIC

INFORMATION

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a method of displas ing audio or visual traffic information.

2. Description of the Prior Art

Advances in technology and the increasing pressures of congested road environments have encouraged the development and adoption of Personal Navigation Devices (PND).

The abbreviation PND is sometimes used to refer to a portable navigation device', but in this specification will be given its more expansive definition, covering any kind of personal navigation device that is either portable (e.g. can he fixed to an auto windscreen IS using a suction mount), or embedded (e.g. permanentls fixed into an automobile). PNDs can be dedicated navigation devices (e.g. a device whose primary function is navigation) or can have multiple other applications (e.g. media plas ers) or can have a primary Rinction other than navigation (e.g. they may be a mobile telephone). PNDs are used predominantly, but not exclusively, in cars and other motor vehicles. PNDs incorporate geographical map databases including road information and points of interest. Thes generally include software which allows the user to input a destination and to be provided with one or more routes; driving instructions are issued to guide the driver along thc selected route to the destination. The PND ma include a mount attachable to an automotis e windscreen.

The selection of the route along which to guide the driver can be ven sophisticated, and the selected route may take into account existing and predicted traffic and road conditions, historical information about road speeds, and the driver's own preferences for the factors determining road choice. In addition, the device mas continually monitor road and traffic conditions, and offer to or choose to change the route over which the remainder of the journe is to be made due to changed conditions.

Road travel is a maj( )r part of everyda life for businesses, for other organizations, and for private individuals. The costs of traffic delays can be very large. The purely financial cost has been estimated as billions of pounds in the UK alone. Gien these costs, systems which can assist drivers to optimize their travel, for instance bs selecting the best route and by avoiding congestion delays, are of significant value. In fact a diverse arra of driver infirmation systems has grown up. The longest established are broadcast radio traffic reports which aggregate data from a number of sources such as the police, eve-in-rhe-sk, and more recently mobile phone calls from drivers stuck in traffic jams, to provide subjective advice about incidents and dehi s. Radio Data System (RDS) radios make these systems more effective by automatically cutting to traffic reports from normal radio programmes. Static route planning systems are provided on the websites of major motoring organisations such as the Automobile Association (AA) and RAC plc in the UK. These allow a driver to enter the points of a journey and to he ven a route and driving instructions for that route.

in the recent past, global positioning system (GPS)-based in-vehicle personal navigation devices hae been introduced. Examples of these are the TomTom GO9 series of PNDs. Personal navigation devices use the GPS system to discover the exact position of the vehicle on the road network and to plot the location of the vehicle on an on-screen road map. PNDs contain a mechanism for computing best or good routes between two or more points on the road network and can direct the driver along the chosen route, continually monitoring their position on that route. Personal navigation devices have begun to incorporate traffic information into their services, and in some, traffic information is integrated into the route selection process: the PND will route around congested roads. Vhere traffic intbrmation is provided b; the PND, the user can observe dela s where the' impact the selected route, and guide the device to re-plan a route aoiding the dela ed sections of road if the consider this necessary. Real time traffic monitoring systems, based on various technologies (e.g. mobile phone calls, fixed cameras, GPS fleet trackin are being used to identify traffic delays and to feed the information into notification systems.

Government organizations charged with managing the transport network have installed static traffic cameras at key locations on the road network. The images from these cameras are presented on public websites in order to give drivers immediate visual information about the state of the roads.

Each of the above systems has unique strengt-bs and weaknesses. \X bile a personal navigation device can provide what is in a formal sense optimal advice for the route to take on a particular journey, this advice may be disregarded by the driver if the route proposed seems unusual, or if there is no supporting evidence for the route selection.

C1earl, an unusual route selection ma) he made when the normal best route suffers severe congestion or an accident.

It is known that static traffic cameras can provide very direct information. A user can see queues of vehicles on a congested section of road, or moving slowly through a section of roadworks. Weather conditions in the area monitored by the camera provide extra information about likely traffic conditions: snow, heavy rain or had visibility may provide the driver wit-h a reason to postpone their journe. on the negative side, traftic cameras cannot easily be consulted during a journey: the driver must plan ahead and check them before setting ofC typically from an internet connected PC.

Broadcast radio reports can be very reassuring, and tend to be trusted. They are also very easily available. But a driver who wishes to depart may have to wait up to 25 minutes or more after their desired departure time for the next traffic report which contains information relevant to their trip.

The integration of some of these traffic information systems into PNDs can provide benefits. A driver who checks their regular route when setting off, or after setting off, and sees congestion, may ask their PND for a route which avoids the congestion.

PNDs may consist of a small box with a screen; PNDs ma)-be installed or carried in a vehicle. PNDs typically contain a GPS receiver in order to accurately locate the vehicle in which it is installed and determine the vehicle's orientation. The user interacts with the PIN!) to tell it the lournev the) wish to make. The device selects a route for the journey.

The user may intervene in, or guide the route selection process. The device provides visual and audible instructions to show the user the vehicle's current position and to guide i-he user along a chosen route. User interaction with the device may be b) a touch screen, by steering column mounted remote control, by voice activation or by any other

suitable method.

PNDs may contain a communications m)dule which allows them to connect to the internet. A PND may communicate using the Bluetooth short-range radio communication system to a General Packet Radio Service (GPRS)-enabled mobile telephone, and from the mobile phone to the internet. An internet connection allows a PNT) to receive or transmit any information as long as the volume is not too large and a protocol can be agreed for the communication. A PND may download road delay information to display or integrate into route selection or it may download weather information relevant to the route.

A PND is generall implemented as a small programmable computcr, consisting of: a IS central processor unit (CPU); memory for storing and running programs and data; persistent memors for retaining programs and data permanenth; a displa, and a set of input and output systems. A modem embedded CPU is significantly more powerful than the CPU of a general purpose computer from 5 or 10 years api, and can easily support running a general purpose operating system such as some variant of Unix. Such systems frequently run an implementation of the free Linux or Berkeley Software Distribution (B SD) operating systems. Persistent memory may he implemented as a hard disk or as some form of non-volatile RAM. In the case of a PND the display may be the touch screen unit. PND input and output systems ma) include a touch screen, voice acthation, or remote control over Bluetooth.

Providers of PNDs and other embedded computing platfbrms provide development kits to assist computer programmers in creating novel or extended applications for their platforms using standard software development procedures. This serves to encourage improvements to the core application, and promotes an ecosystem of software applications and extensions for the platform which may contribute to its market success.

SUMMARY OF THE INVENTION

A first aspect is a method of displaying audio or visual traffic information, the method being deplored in a navigation device, the method comprising the step of displaying a route superimposed on a road map, togethcr with one or more symbols each indicating a location fhr which audio or visual traffic information exists, each symbol being selectable to phi back the audio or visual information.

Non-limiting, optional details are as follows: The visual traffic information might be still or video images, ft ir example generated by one or more fixed traffic cameras, or even cameras (e.g. in a PND itself) operated by end-users sharing that information over a network. The visual traffic information might be generated by or obtained from a web site or from a television service. Audio traffic information might be generated b or ohtained from a radio broadcast service or a television audio feed, or generated by or 1 5 obtained from a web site. The traffic information could also be broadcast or otherwise distributed with location identif3 ing data. The term plas back' implies that the information is stored; in this specification, it also includes information being played in real-time -for example a real time video feed from a traffic camera without prior local or remote storage (other than the transient storage that is part of the normal broadcast process).

One implementation of the device includes a touch screen display and the symbols are then each large enough to be reliably selected using a fingertip (e.g. the symbols could be each at least 0.3cm x 0.3cm). The device may also include (or be connected to) a voice recognition engine, enabling a user to simply speak an appropriate control message to initiate playback of the audio or visual information (e.g. "Show traffic camera No. 3'). In any event, the symbol may consist solely of text description, or be a graphic or icon that ma) conform to the appearance of P01 (point of interest) symbols: for visual traffic information, the symbol may graphically represents a camera and for audio traffic information it may graphically represent a microphone. it may be a thumbnail image -e.g. an actual thumbnail image of a video frame from a traffic camera.

In a touch screen implementation, when the user touches the screen in the vicinity of a symbol fin visual traffic information, the latest image or sequence of images for the location associated with that symbol is displayed for a defined number of seconds..

Similarh, when the user touches the screen in the vicinity of a symb 1 fin audio traffic information, the latest audio report for the location associated with that symbol is played back. Also, when the user touches the screen in the vicinity of a symbol for visual traffic information, the latest image for the location associated with that symbol may he displa ed until the user manually chooses to return to the map b touching the screen or using 5ome other control. Likewise, when the user touches the screen in the icinit of a symbol fi,r audio traffic information, the latest audio report fhr the location associated with that symbol is played back until the user manually chooses to return to the map b) touching the screen or using some other control.

other implementation specific, optional features are: 1 5 * when audio or visual traffic information for a location is played back on the device, the device shows a menu option that enables the user to include or exclude that location from a route. Each traffic camera image (or, more generally, each plas back of audit) or video traffic information), can be accompanied with route calculation options, such as a button labelled include in route' and another button labelled exclude from route'. Touching the include in route' button then causes the route calculation algorithm (typically running on the PND itself) to calculate a route that goes past the traffic camera (or location otherwise referenced in the traffic information); touching the other button leads to a route being calculated that avoids that particular camera.

* the device can be configured to displa a sequence of the images along the route from a set of cameras along the ii)ute, when requested by a user command. The images may be displa ed in the same order as the cameras along the route: each is displaed for a short time or until the user manually selects to display the next image, froni the next camera, or to cancel the sequence. The sequence of images from successive cameras may also he interleaved with the map display highlighting the symbol pertaining to the camera which produced the image it is about to displa. The sequence can include finward and back controls to allow the user to flexibly move to the images which are most interesting to them.

* the device may take advantage of the order of images required for a slide show to download the images from the network in expected display order, minimizing the delay to the user before all hut the first image is displa ed on screen. The expected first image of a slide sho may be downloaded immediately (and also automaticaHv -i.e. without any specific user request) a route has been selected, so that there is no delay at all hefhre the slide show begins, when it is requested.

* audio or isual traffic information can he for locations on a planned route; e.g. the cameras are those cameras associated with the planned route or altcrnaties to that route.

* audit) or visual traffic information can be used before or indepcndentlv of selecting a route.

* the user may choose to view camera image displays within an area that is of interest, either hefhre selecting or requesting a route, or entirely independently of selecting a route.

* the device can be requested to show a slide show of all the visual traffic information from a set of cameras in an area.

* the order of display of the camera images is selected by the device; the device selects the order of display of the camera images by scanning the area and displaying the camera images in the same sequence order as the sequence of camera distances from the user's current location; the camera image from the camera nearest to the user's current location is displayed first, and the camera image from the camera furthest from the user's current location is displayed last.

* the slide show is automatic in that each camera image is shown for a few seconds before proceeding to the next image; or the slide show is non-automatic in that the user must touch the screen, or issue some other command, to request the system to display the next image.

* the device can support the download and display of video clips from the internet.

* a video clip of traffic moving through the camera area is shown when the camera is selected via a camera symbol on a map.

a series of video clips are shown, one clip per camera, when a slide show of the cameras on a route or in an area is requested.

* the traffic information which is disp1a cd is displayed together with a symbol which indicates the traffic direction corresponding to the direction in which the user wishes to travel. This applies to 1) 0th visual as well as aUdio traffic informatlim.

the symbol which is displayed to represent the presence of visual traffic information at a location is displayed together with further 5) mbols \vhich indicate [hr which viewing directions visual traffic informatkrn is available [hr that location.

* Another approach is for an arrow to be superimposed over the actual lanes that form part of the route; this ma require pattern recognition software able to determine the edges of the road and to morph or alter the shape of an arrow so that it is shown in the correct orientation and perspectie as though forming part of the road surface.

A second aspect of the invention is a proxy server operable to supply audio or visual traffic information to a navigation device, the navigation device itself being operable to display a route superimposed on a road map together with one or more symbols each indicating a location for which audio or visual traffic information exists on the sen er, each symbol being selectable to play hack the audio or visual information, the sen-er adapting the audio or visual information for the specific playback requirements of the navigation device.

The proxy server is supplied with (or requests) data from audio or visual traffic information sources; it can act as middleware, in effect taking in data feeds for audio and visual traffic information and adapting that information to conform to a standard, or extracting data from that incoming information and re-packaging that data in a standard format suitable to bandwidth efficient broadcast or transmission to PNDs.

Other oponal features of the proxy server include the folloving * the proxy server converts the images to a format which can be read by PNDs.

* the proxy server scales or clips the image to the PND form factor.

* the proxs server compresses the image to the minimum detail level visible on the PND screen.

* the proxy server reduces the frame rate of the video to a minimum consistent with keeping the video viewable on the device; the frame rate may be as low as frames per second.

* the proxy sen-cr encodes the resultant video using an A/V encoding standard such as MPEG-4 in order to ield highly compressed video data.

* the pnixy server can select traffic reports from the internet, or from broadcasts.

* the proxy sen-er can store the traflic reports as audio streams indexed by tile station coverage area.

* when a user of tile device makes a request, the latest reports from stations which intersect the geographical area of interest to the drier, or from stations in the geographical area through which the dri er is being routed h the device, can he transmitted to the device and pla ed hack Iw it.

A final aspect is a method of providing audio or visual traffic information to a navigation device, the navigation device being operable to display a route superimposed on a road map, together with one or more s mhols each indicating a location for which audio or visual traffic intbrmation exists, each symbol being selectable to play hack the audio or isual information, the method comprising the steps of: (a) a prox) serer obtaining or being proided ith audio or visual traffic information from one or more sources of that information; and b) the proxy sen-er manipulating the information for reproduction on the device.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a PND screen view, presenting a map which shows the current li)catjon, the destination, and the approximate positli)flS of two traffic cameras with respect to the road network.

Figure 2 is a PND screen view of traffic camera image data obtained from camera I in Figure 1.

Figure 3 is a PND screen view of traffic camera image data obtained from camera 2 in Figure 1.

Figure 4 is an image of a PN1) device which is an example of the invention and which is carrying out an example of the invention.

DETAILED DESCRIPTION

With a complex PND system, it is beneficial to give the user clear and simple infbrmation which validates the adice given h' the personal navigation device. A mechanism is described which enhances PNDs with still images, video and audio relevant to traffic conditions in the vicinit of a driver and on the route of an journey the propose to make in order that the driver can be presented with and review audio and/or visual (A/\') inlbrmation relating to their journey. The mechanism described here allows the validation of route selection using still images, video and audio. This provides a much improved interaction experience for the user of a PND and improves the driver's confidence in the advice offered by the device. The driver will be reassured when it is clear that the advice is accurate. Equall, the mechanism allows a driver to review A/V information relating to possible routes, or independently of any route; he may for example simply he curious to see traffic conditions on a given road.

In an implementation of the present invention, a PND can be enhanced to repest or be sent A/V data such as images, video or sound, from a communications network, f r example from an internet location or directly from the GPRS network provider's systems. Or the PND can be registered with a network service which pushes A/\T data to it. The PND can then present images and video on screen and audio over loudspeakers when requested by the control system of the PND. Where such A/V data consists of traffic camera images, the PND can provide an interface to alk)w the search, selection and display of images from traffic cameras on or near to a route, or in a specified geographical area. The traffic cameras used in this invention may be those cameras associated with a planned route or with alternatives to that route. Image data ma also be that recorded using a camera on a mobile phone; such data may be collected b a PND, then transmitted to a network for use as camera information which relates to traffic.

image data may be that recorded by a television service. Where the A/V data is audio, the PND can provide mechanisms to allow the selection and playback of audio streams.

This may consist of recent traffic reports from local radio stations located in the geographical areas of interest, or audio obtained from a television service, of any other useful audio information uploaded to the PND, or of audio synthesised from other information, such as from web page information, in order to present it most conveniently to the user of the PND. Any piece of A/V data may be supplied together with location identifiers, such as spatial coordinates such as latitude and longitude, which identify the place to which the infbrmation relates. For camera data, this may be provided with direction indicating data such as the direction in which the camera is pointing, such as ma he represented by a compass hearing for example.

Traffic Camera Image Presentation Traffic camera images can be selected for download from the Internet, and display on the PND screen, in a number of ways. For example, for the display of Camera Images relevant to a chosen route, when a route has been selected the device will display the route superimposed on a road map, with symbols indicating the location of traffic cameras additionall superimposed. The symbols vil1 he large enough to he reliably selected using a fingertip: such symbols will he at least 0.3 cm hy 0.3 cm iii area. The I 5 symbol relating to visual traffic data ma) resemble a camera. The symbol relating to audio traffic data ma) resemble a speaker or a microphone. An arrow or other direction indicating symbol near to each traffic camera symbol may he included; this points in the approximate direction in which the traffic camera is pointing, to help the user to understand on which part of the camera image to look for the traffic which is travelling in the same direction as the user's possible route. Alternatively, the traffic camera symbol may he oriented so that the direction in which the traffic camera symbol is pointing is approximately the same as the direction in which the traffic camera is pointing. The PND can be configured so that when the user touches the screen in the vicinity of a camera symbol, the latest image from the indicated camera is displa ed for a defined number of seconds. The displa then returns to the map. The device can alternatively be configured so that when the user touches the screen in the vicinity of a camera symbol, the latest image from the indicated camera is displayed until the user manually chooses to return to the map by touching the screen or using some other control.

Where traffic camera images fot opposite directions from approximately the same place on a route are available, the default ma) be for the PND to displa the camera image from the camera which is pointing in approxiniatek the same direction as the direction along the route in which the user wishes to travel. However, this may not always be available, as one of the two cameras may not be working, or traffic camera cost installation reasons niay mean that only one traffic camera is present at a particular location, for example. It may be preferable to include an arrow in the map image only for the exceptional cases in which the camera is pointing airing the direction which is opposite to the route direction in which the user wishes to travel. If a user wishes to check the available camera image data very thoroughly, thc user may wish to review the camera images for both possible directions from a particular direction. in this case, two arr( iws each pointing in opposite dirccti ins will be shown on the map image. By selecting each arrow in turn for example, the user can thereby view' the camera image for each respective camera pointing direction. Within a camera image, optionall a symbol or word can be displayed which indicates whether the direction shown is approximately parallel to or approximatel opposite to thc direction in which the user wishes to travel.

For example, an up arrow may he used to show a parallel direction; a down arrow may he used to show an opposite direction.

The PND must perform a calculation so as know if a given camera image is approximately parallel to the user route, or is in the direction approximately opposite to the user's route. The direction of the camera is received along with its position coordinates. The PND is able to calculate the direction of the user route at the point where the camera is located. The angle between these two directions may be calculated in a number of ways, as will be obvious to one skilled in art. One way is to construct unit vectors for the two directions in the plane of the map. The angle between the two directions is then gien b the inverse cosine of the mathematical vector dot product between the two unit vectors, if the angle is less than 90 degrees, the camera direction can he taken to he approximately paraliel to the user's route. if the angle is greater than degrees, the camera direction can be taken to be approximately opposite to the user's route. If the angle is exactl 90 degrees, the camera direction is unclear with respect to the user route, and ma he represented by a query symbol. A greater level of sophistication could be used by displaying an arrow on the camera image and on the map which is at a continuously variable angle, the displayed angle being that obtained using an inverse trigonometric function and a vector mathematical calculation.

The PND can be configured to display a sequence of the images from successive cameras positioned along the route, when requested to do so by a user command. In this instance, an image from cacti rele ant camera is displayed. The images are typically disp1a ed in route order, and each is displayed for a short rime or until the user manually selects to display the next camera image, or to cance] the sequence. The sequence may he interleaved with the aforementioned map display highlighting the symbol pertaining to the camera hich produced the image it is about to disp1a, as well as possibh an arrow showing the approximate direction in which the camera is pointing, and ma include fonvard and back contn ds to allow' theuser to mo e flexibly to the images which are most interesting to them.

The PND ma) take advantage of the order of images required for a slide show to download the images from the network in expected display order, minimizing the delay to the user before all but the first image is displayed on screen. The expected first image IS of a slide show may he downloaded immediatels a route has been selected, so that there is no deJa) at all before the slide show' begins, when it is requested.

When audio or visual traffic information for a location is played back on the device, the device shows a menu option that enables the user to include or exclude that location from a route.

Display of Camera Images in an Area The user ma) choose to view camera image displa's within an area that is of interest to them, either before selecting or requesting a route, or entirel) independently of selecting a route. For instance if a driver commonly travels the same route, they may use the device to reviex the cameras on that route before or after setting off. Where this shows no problems, the driver might proceed on their way without asking the device to find a route. ()nh where the camera review shows congestkrn might the driver feel the need to request that the device select a route, to determine if their usual route is still the best.

Where the camera images are related to an area, the device will displa the road map of the selected geographical area, with camera s mhols superimposed, as well as possihh arrows showing the approximate direction in which each camera is pointing. The user can select the camera, and the device will download and display the latest image from that camera.

The device can he requested to show a slide show of all the cameras in an area. An order of display can he selected by the device, for instance scanning the area and displaying the image from the camera closest to the user's current location first, and thereafter in distance sequence, with the furthest away last. This slide show can he chosen to be automatic i.e. to show each camera image for a few seconds, then move on to the next, or manual i.e. touch the screen, or issue some other command, to request the device to displa the next image.

\ hen the user of a device invokes it, the latest reports from television or radio stations which intersect the geographical area of interest to the user, or being routed over by the device, can he transmitted to the device and played back b it.

The device can be configured to use a mode of operation which will not distract the driver's attention from the safe operation of their vehicle. For instance, if rules are defined to cause the PND to automatically and repeatedly display appropriate images in sequence, the driver need not be interrupted by the PND, but need only view it when it is safe to do so. in this way, the device can provide guidance and interaction while the driver remains safe and behaves legally: in many jurisdictions the law requires or implies that the driver should not allow their attention to be distracted by an in-vehicle device such as a PND. An example in the UK is the 1988 Road Traffic Act. Of course, in the UK it is perfectly legal for a passenger to operate a PND interactively.

Downk)ad and Compression In current implementations of mobile communications networks, communications costs and delays can be significant when transmitting data of the size of images. In addition, different camera images may be made available in different sizes, scales and image formats. These problems can be mitigated b directing image requests through a proxy server which is attached to the fixed internet. in this arrangement, when the PND requires a camera image at a particular location, or a number of images in an area, it makes the request to the proxy sen-er. The proxy sen-er in turn requests the images from their various original locations, and receives them extremely quickly over the fixed internet. The proM server may obtain data fn m the internet, or from audio or video broadcasts. Alternatively, the pro sen-er may receive data sent to it by external sources, S such as on a periodic basis, such as every half hour, or when there is significant news to report. The proM server then converts the images to a format which can he read by the PND, scales or clips the image to the PNI) form factor, and compresses the image to the minimum detail leel isihle on the PND screen, or to a le'el of detail hich is less than the minimum detail level visible on the PND screen. Images may be supplied in black and white, as a black and white image requires less bandwidth than a colour image. An image processed in this way can usually be downloaded to a PND over GPRS in I or 2 seconds, thus enabling the image display mechanisms we have described.

Traffic Camera \ideo Presentation The s stem can support the download and display of video clips from the internet. The same systems of user interaction are employed to select video clips as are used to select still images: a video clip of traffic moving through the camera area is shown when the camera is selected via a camera symbol on a map, or a series of video clips are shown, one clip per camera, when a slide show of the cameras on a route or in an area is requested.

Video Compression In order to address the time and cost to download video clips over current communications networks (for example GPRS), a proxy server is used as an optional part of the srstem. The proxy server fetches original video clips over the fixed internet, and transforms them so that the) are of the minimum size compatible with displa on the PND. This reduces to acceptable levels the cost and time to download the clips. The proxy server clips frames of the video to the aspect ratio for the PND screen. The proxy server compresses individual frames so that the hae no more detail than is visible on the PND screen, or to have less detail than is visible on the screen. This can result in a large reduction in the data size required. The proxy server may reduce the frame rate of the video to a minimum consistent with keeping the video viewable on the PND. This frame rate mas be as low as 5 frames per second fin a simple video such as that of ehicles moving past a static camera. The proxy server encodes the resultant video using a sophisticated A/V encoding standard such as MPEG-4 in order to yield highly compressed video data. Such encodings can factor out static hackground, and other common elements of successive images in a video clip, and only transmit the differences between one scene and the next. The constrained application of compressing traffic camera video clips is particularis amenable to such compression techniques, and can yield a \ideo clip which encodes a few seconds of video at low frame rates in a size which is not orders of magnitude larger than the size of a still image.

Radio Report Storage and Presentation 1 ocal and national radio stations transmit periodic traffic reports. The proxy sen-er can 1 5 select traffic reports from the internet, or from broadcasts, using the RI)S system. The proxs server can then store these reports as audio streams indexed bs the station coverage area. When the user of a PND invokes them, the latest reports from stations which intersect the geographical area of interest to the driver, or from the route being used by the PND, can be transmitted to the PND and played back by it. The PND has a speaker which is used to issue verbal driving instructions. This speaker can be programmed to plas back downloaded affic reports when they are selected. The map interface used to select traffic cameras for image display may be augmented with symbols indicating audio traffic reports, including reports which refer to particular locations on the map. These can be selected for playback bs touching the screen or bs ans' of the other control mechanisms already described.

Example of Implementation Here is an example of an implementation using the touch screen for a user to examine cameras on alternative possible routes. Figure 1 shows the map of the travel area displased on the PND screen 10. Note that the position of the vehicle in which the PND is installed is indicated, as is the requested destination and the approximate locations of two static traffic cameras. The user touches the camera icon shown in the screen to select camera 1. The PND downloads the appropriate image from the proxy server. Figure 2 shows the image shown on the PND screen 20 from camera 1. By the direction of the an. w near to camera I in Figure 1, camera 1 is pointing in the opposite direction to the user's possible route past camera 1. This example is in the UK, where traffic drives on the left. Therefore because the image shows congestion on the side of the road on which the traffic is travelling in the opposite direction to the direction in which the camera is pointing, the user's possible route is suffering from congestion. This is in contrast to the traffic traeIling in the direction in which the camera is pointing, which is not suffering from congestion. This example shows clearl the benefit of informing the user of the 1 0 approximate direction in which the camera is pointing, as if the user did not know in which direction the camera was pointing, they would only have been able to infer that there was a 50:50 chance of encountering congestion near to camera 1. This is a very important benefit, as typically when congestion occurs, it occurs for traffic travelling in one direction and not for traffic travelling in the opposite direction. The arrow 21 in Figure 2 shows that the camera taking the image is facing along the direction which is approximatel opposite to that in which the user wishes to travel, because this is the meaning of an arrow which is pointing down. Another approach is for an arrow to he superimposed over the actual lanes that form part of the route; this may require pattern recognition software able to determine the edges of the road and to morph or alter the shape of an arrow so that it is shown in the correct orientation and perspective as though forming part of the road surface.

The drier returns to the map view of Figure 1 to investigate alternative route options.

On viewing the image in Figure 1, the driver decides that the route passing camera 2 ma he a good alternative. Figure 3 shows the image 30 displayed by the PND when the traffic camera 2 of Figure 1 is selected. The arrow 31 in Figure 3 shows that the camera taking the image is facing along the direction which is approximately parallel to that in which the user wishes to travel, because this is the meaning of an arrow which is pointing up. In Figure 3, because the direction in which the camera is pointing is approximately parallel to the intended journey direction, only one car is visible in the lanes for the direction in which the user wishes to travel. Based on the image in Figure 3, this route seems to be much less congested, so the driver decides to take the route past camera 2.

At this point, the driver might ask the PND to calculate some routes. Amongst the routes uttered by the PND, the optimum route offered by the PND would depend upon whether the routing system was aware of the delays at the camera 1 location, and what account it made of them in route selection. But it is clear that where there are cameras, the traffic camera images ha'. e given the driver a good idea of the correct route to take.

The dri'. cr may select a n rnte which passes by camera 2, such as by including the road hs camera 2 as an intermediate point in the route. This can he facilitated b accompanying each traffic camera image (or, more generally, each playback of audio or video traffic information), with route calculation options, such as a button labelled include in route' and another button labelled exclude from route'. Touching the include in route' button then causes the route calculation algorithm (u-picalh running on the PND itselO to calculate a route that goes past the traffic camera (or location otherwise referenced in the traffic information); touching the other button leads to a route being calculated that avoids that particular camera. The route calculation algorithm may well use other kinds of traffic data in performing its calculations (e.g. road traffic sensors, movement of mobile telephones across the cell network etc.); hence, a tspical PND ma displa icons indicati'.e of roadworks, or major accidents super-imposed o'.er a navigation map or a schematic showing the planned route. It is well known that the quality of the traffic inflirmation can be very variable, not least because it comes from many different sources.

Hence, it is not unknown tbr a major traffic jam to be completely unreported by mans conventional traffic systems; with the present approach, a driver, seeing a traffic jam ahead, can ask his PND to display the P01s for all traffic cameras (this can be done using the standard P01 selection process in which a user marks a check box for all P01 types that are to be displa ed). The PND then downloads the appropriate traffic camera data (which may be the most recent still image, or in some cases a real time video feed) and the driver can then select the traffic camera POT symbols for the cameras along sa the next 5 miles of his route so that he has actual visual confirmation of what the traffic jam really looks like.

An image of a device 40 running an experimental system of the invention for traffic camera display 42 is shown in Figure 4. In Figure 4, the camera location is indicated on a map 41 together with an arrow which shows the approximate direction in which the camera is pointing. This is an example of how traffic camera images might look on a real-world PND. The white arrow 43 in Figure 4 shows that the camera taking the image is facing along the direction which is approximateh parallel to that in which the user wishes to travel, because this is the meaning of an arrow-which is pointing up.

The device described above allows a variety of A/\' information Sc urces on a communications network to he used to enhance the information provided by a personal navigation device. The mechanism for integrating the loading and viewing of traffic camera images with the route guidance and route selection facilities of a PIN!) is a particular instance of this information enhancement. Other examples of A/\' information enhancement have also been outlined. The application of image and video compression technic1ues and the use of a proxy sen-er allow the data to be loaded onto the PND in real time and in an efficient manner. Although the use of PNDs has been emphasized above, it will be appreciated by those skilled in the art that the 1ND could instead he an embedded automotive navigation device.

Various modifications and alterations of this invention will become apparent to those skilled in the art without departing from the scope of this invention, and it should be understood that this invention is not to he unduly limited to the illustrative embodiments.

Claims (61)

1. A method of displaying audio or visual traffic information, the method being dcploved in a navigation device, the method comprising the step of displaying a route superimposed on a road map, together with one or more symbols each indicating a location for which audio or visual traffic information exists, each symbol being selectable to play back the audio or visual information.

2. The method of Claim 1, wherein the traffic information is visual traffic 1 0 information comprising still or video images.

3. The method of Claim 2, wherein the visual traffic information is generated by a fixed traffic camera.

1 5

4. The method of Claim 2, wherein the isuaJ traffic information is generated b) cameras operated b end-users sharing that information over a network.

5. The method of Claim 4, wherein the visual traffic information is generated by portable navigation devices sharing that infbrmation over a network.

6. The method of Claim 2, whcrein the visual traffic information is generated by or obtained from a web site.

7. The method of Claim 2, wherein the visual traffic information is generated or obtained from a television sen-ice.

8. The method of Claim 1, wherein the traffic information is audio traffic information that is generated by or obtained from a radio broadcast service.

9. The method of Claim I, wherein the traffic information is audio traffic infbrmation generated bs a teleAsion audio feed.

10. The method of Claim I, wherein the traffic information is audio traffic information generated b or obtained from a web site.

11. The method of Claim 1, wherein the traffic information is broadcast or otherwise distributed with location idenrihing data.

12. The method of Claim I, wherein the device includes a touch screen display and the symbols are each large enough to be reiahh selected using a fingertip.

13. The method of Claim I wherein the c]e*ice includes (or is connected to) a voice recognition engine, enabling a user to simpl speak an appropriate control message to initiate playback of the audio or visual information.

14. The method of Claim 1, wherein the device is a Personal Navigation Device that includes a mount attachahie to an automotive windscreen.

15. The method of Claim 1, wherein the device is an embedded automotive navigation device

16. The method of Claim 12, wherein the symbols are each at least 0.3 cm x 0.3 cm.

17. The method of Claim 1, wherein the svmhol is an actual thumbnail image of a video frame from a traffic camera.

18. The method of Claim I in which the symbol consists solely of text description.

19. The method of Claim 18 in which the symbol is a graphic or icon.

20. The method of Claim 19 in which the graphic or icon conforms to the appearance of P01 symbols.

21. The method of Claim 20, wherein the symbol for audio traffic information graphically represents a microphone.

22. The method of Claim 20, wherein the symbol graphically represents a camera.

23. The method of Claim 1, wherein when a user touches the screen in thc vicinity of a symbol for visual traffic information, the latest image or sequence of images for the location associated with that s mhol is displayed for a defined number of seconds.

24. The method of Claim 1, wherein hen a user touches the screen in the vicinit of a symbol br audio traffic information, the latest audio report for the location associated with that symbol is played back.

25. The method of Claim 1, wherein when a user touches the screen in the vicinity of a symbol for visual traffic information, the latest image for the location associated with that symbol is displayed until the user manually chooses to return to the map by touching the screen or using some other control.

26. The method of Claim 1, wherein when a user touches the screen in the vicinit of a symbol for audio traffic information, the latest audio report for the location associated with that symbol is played back until the user manually chooses to return to the map by touching the screen or using some other control.

27. The method of Claim 1, wherein when audio or visual traffic information for a location is plaed back on the device, the device shows a menu option that enables the user to include or exclude that location from a route.

28. The method of Claim I, wherein the device can be configured to display a sequence of images along the route from a set of cameras along the route, when requested by a user command.

29. The method of Claim 28 wherein the images are displayed in the same order as the cameras along the route, and each is displayed for a short time or until the user manually selects to displas the next image, from the next camera, or to cancel the sequence.

30. The method of Claim 28 wherein the sequence of images from successive cameras ma be interleaved with the map display highlighting the symbol pertaining to the camera which produced the image it is about to display.

31. The method of Claim 28 wherein the sequence includes forward and hack controls to allow the user to t1exihl move to the images which are most interesting to them.

32. The method of Claim 28 wherein the device takes advantage of the order of images required fi r a slide show to download the images from the network in expected display order, minimizing the delay to the user before all but the first image is displayed on screen.

33. The method of Claim 28 wherein the expected first image of a slide show ma be downloaded immediately a route has been selected, so that there is no dela at all before the slide show begins, when it is requested.

34. The method of Claim 1, wherein audio or visual traffic information are for locations on a planned route.

35. The method of Claim I, wherein audio or visual traffic information is used before or independently of selecting a route.

36. The method of Claim 3, wherein the cameras are those cameras associated with the planned route or alternatives to that route.

37. The method of Claim 3, wherein a user may choose to view camera image displays within an area that is of interest, either before selecting or requesting a route, or entirely independently of selecting a route.

38. The method of Claim 3, wherein the device can he requested to show a slide show of all the visual traffic information from a set of cameras in an area.

39. The method of Claim 38, wherein the order of display of the camera images is selected by the device.

40. The method of Claim 39, wherein the device selects the order of display of the camera images b scanning the area and displaying the camera images in the same sequence order as the sequence of camera distances from the user's current location, whereby the camera image from the camera nearest to the user's current location is displaed first, and the camera image from the camera furthest from the user's current location is displayed last.

41. The method of Claim 38, wherein the slide show is automatic in that each camera image is shown for a few seconds before proceeding to the next image.

42. The method of Claim 38, wherein the slide show is non-automatic in that the user must touch the screen, or issue some other command, to request the system to displa the next image.

43. The method of Claim 1, wherein the device can support the download and display of video clips from the internet.

44. The method of Claim 43, wherein a video clip of traffic moving through the camera area is shown when the camera is selected via a camera symbol on a map.

45. The method of Claim 44, wherein a series of ideo clips are shown, one clip per camera, when a slide show of the cameras on a route or in an area is requested.

46. The method of Claim 1, wherein traffic infbrmation is displayed together with a symbol which indicates the traffic direction corresponding to the direction in which the user wishes to travel.

47. h method of Claim 1 wherein the s mbol, which is displas ed to represent the presence of visual traffic information at a location, is displa) ed together with further symbols which indicate for which viewing directions visual traffic information is available for that location.

48. A navigation s stem comprising a proxy server and a navigation device, the prox sen-er operable to supph audio or visual traffic information to the navigation device, the navigation device itself being operable to displa a route superimposed on a road map together with one or more symbols each indicating a location for which audio or visual traffic information exists on the server, each s mbol being selectable to play hack the audio or visual information, the server adapting the audio or visual information for the specific pla back requirements of the navigati( in device.

49. The navigation system of Claim 48, wherein the proxy server is supplied with data from audio or visual traffic information sources.

50. Thc navigation system of Claim 48, wherein the proxy server is operable as middle are that takes in data feeds for audio and visual traffic information and adapts that information to conform to a standard, or extracts data from that incoming information and re-packages that data in a standard format suitable for bandwidth efficient broadcast or transmission to navigation devices.

51. The navigation system of Claim 48, wherein the proxy server requests data from audio or visual traffic information sources.

52. The navigation s stem of Claim 48, wherein the proxy server converts an image to a format that can he read b a navigation device.

53. The navigation system of Claim 48, wherein the proxy server scales or clips an image to a navigation device form factor.

54. Thc navigation system of Claim 48, wherein the proxy server compresses an image to the minimum detail level visible on a navigation device screen.

55. Thc navigation system of Claim 48, wherein the prox server reduces the frame rate of the video to a minimum consistent with keeping the video viewable on a navigation device.

56. The navigation system of Claim 4$, wherein the proxy server encodes a resultant video using an A/\' encoding standard such as MPEG-4 in order to yield highly compressed video data.

57. The navigation system of Claim 48, wherein the prox server can select traffic reports from the internet, or from broadcasts.

5$. The navigation system of Claim 57, wherein the prox server can store the traffic reports as audio streams indexed by the station coverage area.

59. The navigation system of Claim 58, wherein when a user of a navigation device makes a request, the latest reports from stations which intersect the geographical area of interest to the driver, or from stations in the geographical area through which the driver is being routed b the device, can be transmitted to the device and played back by it.

60. A method of providing audio or visual traffic information to a navigation system comprising a proxy server and a navigation device, the navigation device being operable to display a route superimposed on a road map, together with one or more symbols each indicating a location for which audio or isual traffic in formation exists, each symbol being selectable to play back the audio or visual information, the method comprising the steps of: (a) the prox server obtaining or being provided with audio or visual traffic information from one or more sources of that information; (b) the prox server manipulating the information for reproduction on the device.

61. A motor vehicle, the motor vehicle including a navigation device operable to display a route superimposed on a road map using a method as claimed in any preceding Claim 1 -47.