Abstract:
This invention provides a diversity system with identification and evaluation of antenna properties. The application also provides a method for selecting an external receiving broadcast diversity antenna. The invention makes a selection of one of the diversity antennas as efficient as possible and is able to adapt the solution found to a variety of practical situations that may arise regarding diversity reception in a vehicle. This may be accomplished by the antenna characteristics being detected and antenna selection made based on the antenna characteristics. Thus, the best reception signal will be automatically selected by the mobile broadcast receiver without human intervention or prolonged waiting time.

Description:
BACKGROUND OF THE INVENTION 
     1. Priority Claim 
     This application claims the benefit of European Patent Application No. 04014262.2, filed Jun. 17, 2004. The disclosure of the above application is incorporated in its entirely herein by reference. 
     2. Technical Field 
     This application is directed to a diversity system with identification and evaluation of antenna properties. In particular, this application is directed to a mobile broadcast reception system to be used for the reception of broadcast signals in a vehicle. 
     3. Related Art 
     Modem vehicles are being equipped with more broadcast reception equipment than merely FM radio. Thus, it is becoming increasingly important to ensure quality reception as well as flexibility of use of equipment mounted in or attached to a vehicle. For example, such equipment may include terrestrial broadcast televisions, including analog, digital, DAB receivers and the like. Because the frequency band and signals for various receivers may be different, different reception antennas may be required. 
     To achieve quality reception similar to reception achieved in a stationary home or work environment, diversity reception antennas may be employed in mobile broadcast reception systems. Diversity reception generally implies spatial diversity. Another method that may be used is cross-polarization diversity, which may address problems associated with restricted space in vehicles. 
     However, a disadvantage with current diversity as employed in mobile reception systems is time varying multi-path fading, with different multi-path intensity profiles. Multi-path fading may arise in wireless broadcast as a result of reflections from stationary and non-stationary objects and is manifested as a random amplitude and phase modulation. At a receiver, multiple copies of a signal are summed together in either a constructive or destructive manner. The destructive addition of the signals may create fading dips in the signal power. The exact phase relationship, and therefore the degree of cancellation, may vary from position to position, making it possible for an antenna at location “A” to experience severe destructive cancellation and an antenna at location “B” to experience constructive addition. The distances involved depend upon frequencies used for transmission and may be small. 
     Diversity techniques aim to improve reception performance by allowing more than one antenna to be used with a common receiver. These antennas may be spatially separated by an appropriate distance or have different polarizations. Thus, selecting the best antenna on a dynamic basis provides some operational advantage such as automatically and dynamically recovering the highest possible signal quality. For example, multi-path fading is especially an issue in orthogonal frequency division multiplexing (OFDM) as generally utilized in digital video broadcast (DVB). OFDM is a method of digital modulation in which a signal is split into narrowband channels at different frequencies. In some respects, OFDM is similar to conventional frequency-division multiplexing (FDM). The difference, however, lies in how the signals are modulated and demodulated. Priority is given to minimizing the interference, or crosstalk, among the symbols making up the data stream. In other words, less importance is placed on perfecting individual channels. 
     Thus, a typical multi-path fading environment may include a signal transmitted from a transmitter received by a receiver mounted in, for example, a vehicle. In this situation, the signal transmitted may be received directly by the receiver, as well as after having been reflected off various objects in the surrounding environment such as buildings and/or trees. These different signals received are not correlated. However, for many scattering environments, spatial diversity is an effective way to improve the performance of wireless radio systems. The signals (at least two) should be received by the diversity antennas and then switched between or combined in the receiver. 
     A standard diversity technique is maximum ratio combining in a receiver, which means that the signal is down-converted into the base band, demodulated and then combined to optimize the signal to noise ratio. Alternatively, in switched diversity, one or the other of at least two antennas is selected and one of the antennas remains selected until the received signal strength falls below some limit of acceptability. At this point, the other antenna is switched and this process is repeated. 
     For example, one system may include a space diversity television broadcast receiver in a vehicle that can detect whether an antenna is connected or not, and subsequently choose the best signal of the connected antennas. In such a system, the video signal only includes the signals from the actually connected antennas, which means that harsh noise may be effectively suppressed. The harsh noise would result from the inclusion of a lacking portion of the video or audio signal resulting from the antenna connector signal during a specific period when one of the antennas is not connected. In practice, an antenna connection detection portion is included in between the respective antenna and tuner, and an unoccupied antenna connector detecting portion outputs a signal to a signal selecting controller which also feeds back into the tuner. In this way it is ascertained that only the signals from connected antennas are compared and can be selected. 
     Systems such as described above have been limited to a particular frequency band and determining whether an antenna is connected or not. However, frequency diversity needs to be employed because sometimes the same program is broadcast in two different frequency bands. Because any two different frequencies may experience different multi-path fading, it would be useful to receive these two different frequencies. Therefore, a need exists for a diversity system with identification and evaluation of antenna properties and more particularly to a mobile broadcast reception system to be used for the reception of broadcast signals in a vehicle which, among other things, is not limited to a particular frequency band and determining whether an antenna is connected or not. 
     SUMMARY 
     This invention provides a diversity system with identification and evaluation of antenna properties. The application also provides a method for selecting an external receiving broadcast diversity antenna. The invention makes a selection of one of the diversity antennas as efficient as possible and is able to adapt the solution found to a variety of practical situations that may arise regarding diversity reception in a vehicle. This may be accomplished by the antenna characteristics being detected and antenna selection made based on the antenna characteristics. This results in the best reception signal always being automatically selected by the mobile broadcast receiver without human intervention or prolonged waiting time. 
     The application also provides the further advantage that the mobile broadcast receiver may be employed with different kinds of diversity. For example, spatial diversity, cross-polar diversity and/or frequency diversity. In other words, the mobile broadcast receiver is not restricted by the antenna and/or antenna diversity design. The mobile broadcast receiver can also determine the diversity antenna circuit identifications, which has the advantage that the mobile broadcast receiver may immediately adapt to the correct antenna, frequency and modulation. 
     The mobile broadcast receiver may also include detectors, with each detector determining the operational characteristics of the antenna connected to it. This is advantageous because the detectors are less complex. The mobile broadcast receiver may also have only one detector, connected to a plurality of external diversity antennas through a multiplexer. 
     Tuning means also may be provided that may receive a digital signal, such as DAB, DVB-H and DVB-T and the like. Analog signals may be received as well. There may be a plurality of tuners that make up the tuning means, whereby each tuner may be assigned to a specific frequency band. Moreover, the mobile broadcast receiver has the advantage that the tuning means may be a Software Defined Radio. This makes the mobile broadcast system more flexible regarding the reception of signals from different frequency bands and standards. 
     The mobile broadcast receiver additionally may have one or more of an antenna impedance detection unit, an antenna directionality determination unit and an antenna frequency bandwidth determining unit. These operational characteristics help establish which antenna should be selected for reception of a broadcast signal. 
     Other systems, methods, features and advantages of the invention will be, or will become, apparent to one with skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description, be within the scope of the invention, and be protected by the following claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention can be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, in the figures, like referenced numerals designate corresponding parts throughout the different views. 
         FIG. 1  illustrates an example of a mobile broadcast receiver system. 
         FIG. 2  illustrates an example of another mobile broadcast receiver system. 
         FIG. 3  illustrates an example of another mobile broadcast receiver system. 
         FIG. 4  illustrates an example of another mobile broadcast receiver system. 
         FIG. 5  illustrates an example of another mobile broadcast receiver system. 
         FIG. 6  illustrates an operational flow diagram for a method of selecting an external diversity antenna. 
         FIG. 7  illustrates an example of another mobile broadcast receiver system. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       FIG. 1  shows an example of a diversity system, which may also be referred to as a mobile broadcast receiver system (MBRS),  100  with identification and evaluation of antenna properties. A broadcast signal  102  may be received by at least one of the external diversity antennas  104 ,  106 , and  108 . While a particular arrangement and number of antennas  104 ,  106  and  108  is shown, different arrangements and quantities of antennas are possible. The antennas  104 ,  106  and  108  may be frequency selective antennas for a specific frequency. For example, the antennas may be FM, VHF, UHF, DAB, DVB, or broadband antennas, or any combination of those frequency bands or even covering the whole frequency range for broadcast reception. Moreover, for example, antennas  104  and  106  may cover the same frequency band and provide spatial diversity for the MBRS  100 . For this purpose, the antennas  104  and  106  may be spaced at multiples of the wavelength. 
     The antennas  104 ,  106  and  108  may be cross-polarized antennas. This means that the resulting diversity is polarization diversity. Cross-polar diversity antennas make use of the fact that in multi-path environments the broadcast signal is reflected off many different obstacles, some of which will change the polarity of the signal. The different reflectors are generally made of different materials, for example, concrete buildings, organic matter on trees, and the metals on vehicles, and therefore their reflective properties may differ. These different reflective properties may induce a change of polarization in the reflected signal. On reception with a single polarized antenna this may mean that a signal with a lesser amplitude would be received and the effect of noise or interference would be generally much greater. With a cross-polarized antenna, the signals of the two polarizations may be utilized and the best signal selected or the two signals may be combined. Frequency diversity may also be employed. 
     There are several different antennas commercially available for the vehicle market. In this application, the term vehicle includes an automobile, motorcycle, spaceship, airplane and/or train, or any other means of conventional or unconventional transportation. These antennas may include four-way diversity vehicle antennas in a whip style for roof installation, as well as windshield mounted cable antennas with two-way diversity for the FM, VHF and UHF bands. Roof antennas may also include analog periodic antennas over a metallic reflector. In light of the foregoing, antennas  104 ,  106  and  108  may be any one or a combination of these types of antennas. However, the principles of this application may apply to an antenna that is developed in the future for vehicular use. 
     The antennas  104 ,  106  and  108  may be connected to the MBRS  100  through antenna connectors  110 ,  112 , and  114 . While three antenna connectors are shown, different arrangements and quantities of antenna connectors are possible. A detector  116  detects operation characteristics of the antennas  104 ,  106  and  108 . The operation characteristics detected by the detector  116  may be, for example, antenna impedance detection, antenna directionality determination, antenna frequency bandwidth of operation determination, information on the antenna matching circuitry, as well as other operation characteristics. The detector  116  uses the information gained to transmit a control signal  118  to the antenna selector  120 . The antenna selector  120  may use the control signal  118  received from the detector  116  as well as other quality indications to choose the signal from the best antenna  104 ,  106  and  108  in, for example, switched diversity. 
     The broadcast signal  102  may also be transmitted from the detector  116  to the antenna selector  120  via a wired or wireless link  126 . The antenna selector  120  selects the signal from at least one of the antennas  104 ,  106  and  108  and outputs the selected signal through the signal output  122  to the tuning means  124 , where the received broadcast signal is turned into a visual television signal and/or an audible radio or other audio signal. 
     The tuning means  124  may include, but are not necessarily limited to, tuners adapted to receive any or all of the following signals: analog signals generally, digital signals generally, FM, VHF, UHF, DAB, DVB-H and/or DVB-T. The tuning means  124  that may be employed may depend on the signal received and therefore which antenna was selected by the antenna selector  120 . The tuning means  124  may also include a plurality of tuners whereby each tuner may be assigned to a particular frequency band. The tuning means  124  may also include a multi-tuner front-end adapted to serve a plurality of frequency bands, an A/D converter, and/or a software demodulator adapted to demodulate a digital signal. 
       FIG. 2  shows a particular embodiment of the MBRS  100 . A broadcast signal  102  may be received by the external diversity antennas  104 ,  106  and  108  and input to the MBRS  100  through the antenna connectors  110 ,  112 , and  114  respectively. Each signal outputted from the antenna connectors  110 ,  112 , and  114  may go to one of three detectors  200 ,  202  and  204 . For example, the signal outputted from antenna connector  110  may go to detector  200 , the signal outputted from antenna connector  112  may go to detector  202 , and the signal outputted from antenna connector  114  may go to detector  204 . It should be understood that output from each antenna connector is not limited to going to a particular connector as shown. The outputs may be wired to any one or more of detectors  200 ,  202  and  204 . The detectors  200 ,  202  and  204  may detect operation characteristics of one or more of the antennas  104 ,  106  and  108 . The operation characteristics detected by the detectors  200 ,  202  and  204  may be, for example, antenna impedance, antenna directionality, antenna frequency bandwidth of operation, information on the antenna matching circuitry, as well as other operation characteristics. Each detector  200 ,  202  and  204  may send a control signal  206 ,  208  and  210 , respectively, to the antenna selector  120  which, as described above, selects the signal from at least one of the antennas  104 ,  106  and  108  and outputs the selected signal through the signal output  122  to the tuning means  124  for further processing. 
     In  FIG. 2 , each detector  200 ,  202  and  204  is responsible for the signal coming from one of the antennas  104 ,  106  and  108 , respectively. This means that, under certain circumstances, each detector  200 ,  202  and  204  may be simplified for dealing with specific antenna characteristics. Each detector  200 ,  202  and  204  may measure the matching circuitry characteristics and the possible coding at the beginning of every cycle, which may occur when the MBRS  100  is turned on or when the frequency band in the tuning means  124  is switched. The operational characteristics of the antennas  104 ,  106  and  108  may be constantly monitored by a detector  200 ,  202  and  204 , and a control signal may be sent to the antenna selector  120 . 
       FIG. 3  shows a detector  300  that may be used for determining the antenna  104 ,  106  and  108  characteristics and matching circuit characteristics of all antennas  104 ,  106  and  108 . In  FIG. 3 , a signal may be received by the antennas  104 ,  106  and  108  and input into the MBRS  100  through the connectors  110 ,  112  and  114 . The signal may then be multiplexed by the multiplexer  302  prior to the characteristics of the antennas  104 ,  106  and  108  being determined in the detector  300 , which in turn may send a control signal to the antenna selector  120 . The signal “selected” by the antenna selector  120  may then be outputted through the connector  122  to the tuning means  124 . 
     The detector  300  has the capability to process the range of frequencies received by the antennas  104 ,  106  and  108  and the capability to determine all possible antenna and matching circuitry characteristics. Thus, the detector  300  may receive FM, VHF, UHF, DAB, DVB and other signals. Within the frequency bands of the received signals there is a possibility for several different antennas and combinations of antennas for diversity. Therefore, there are also many possibilities regarding the matching circuitry, which is explained more below in reference to  FIG. 4 . The multiplexer  302  ensures that the detector  300  deals with one signal at a time. This is advantageous because only one detector  300  is required. For the antenna selector  120 , this means that it may only receive one control signal  304  from the detector  300 . 
     The MBRS  100 , depicted in  FIG. 4 , is the same as that of  FIG. 1 .  FIG. 4 , however, elaborates on the possible configurations for antenna matching circuits, depicted as matching circuits  400 ,  402  and  404  respectively, and the coding that may be introduced. In this application, coding means may include resistors, current sources or voltage sources or the like. Such coding means is advantageous because it is a simple structure for communicating with the MBRS  100  to which antennas  104 ,  106  and  108  are actually connected. 
       FIG. 4  illustrates how a capacitor “C” may be used to decouple the antennas  104 ,  106  and  108  and matching circuits  400 ,  402  and  404  from the coding employed for each antenna from the MBRS  100 . The reasons for including a code with an antenna  104 ,  106  and  108  are many and include potentially faster and simpler operation of the MBRS  100 . If the detector  116  can detect a coded input it can forward the information to the antenna selector  120 , which then has additional information on which to base its selection. The coding may be carried out for example by inserting a resistor “R” between antenna  104  and the input connector  110  and/or connecting a voltage source “V” between the antenna  106  and the input connector  112  and/or connecting a current source “I” between the antenna  108  and the input connector  114 . The values of the resistor R, the voltage source V and the current source I are coded to have a specific meaning to the antenna selector  120 . 
     Different values of the resistor R for example could be as follows and have the following meanings, but not necessarily limited as such: R=10 kΩ and may indicate a passive FM dipole which could be used for antenna diversity for the television receiver especially in band I to III channels; R=20 kΩ may, for example, be an active adhesive laminate antenna which is used for television reception and means that a preamplifier should be switched off in the RF path; R=30 kΩ could indicate a passive laminated antenna for television reception where the preamplifier in the RF path is needed. The value of the resistor R may also be used to indicate whether the receiver is actually mobile or used in a stationary home environment. If, for example, the resistor R has a value of less than 50 kΩ, this may mean that the receiver is used in its mobile mode. If, on the other hand, the value of the resistor R is greater than 50 kΩ, this could be used as an indication that the receiver is actually connected to a stationary antenna or even a cable. This may have the implication, for example, that in the home environment diversity is not required as the signal received does not suffer multipath fading. 
       FIG. 5  illustrates an additional way in which the MBRS  100  may be used. This configuration may be used for Software Defined Radio (SDR) where the MBRS  100  outputs signals through connectors  500 ,  502  and  504  to tuning means  506 ,  508  and  510 . The signal is then processed in the signal processing section  512 . The tuning means in this example may be a multi-tuner front end A/D converter and a software demodulator. SDR means that radio functionality is moved into software and the analog/digital interface is moved closer to the air radio interface at the antenna. One of its advantages is that general purpose hardware may be substituted for dedicated hardware, thereby reducing production costs. 
     The term SDR is used to describe radios that provide software controllers for a variety of modulation techniques—wideband or narrowband operation—and waveform requirements and involving standards over a broad frequency range. The frequency bands covered may still be constrained at the front end, requiring a switch in the antenna system. SDR-enabled user devices may be dynamically programmed in software to reconfigure their characteristics for better performance. SDR offers a solution to accommodate many standards, frequency bands and applications by offering end-user devices that may be programmed, fixed or enhanced by over-the-air software. With SDR, a common hardware platform is implemented and different standards and technologies may be accommodated by software modules. Front-end processing in SDR consists of the physical air interface, the front-end radio frequency processing and any frequency up and down conversion that is necessary, as well as modulation/demodulation processing. The signal processing section  512  may be responsible for the content, information processing for the purpose of decomposition, or recovering the embedded information containing data control and timing. 
     The MBRS  100  allows for a more automatic deployment of the receiving antennas  104 ,  106  and  108 . In this case, the information  514  on the antenna characteristics is also sent from the detector  116  to the signal processing section  512  and the control signal is being sent from the detector  116  to the antenna selector  120 . 
       FIG. 6  illustrates in the form of a flowchart the steps that may occur in the MBRS  100 . A broadcast signal may be received  600  and the operational characteristics of the antennas may be detected  602 . A control signal is sent  604  to the selector, which on the basis of the control signal selects  606  one or more antennas. The signal may then be forwarded  608  to the tuner. It is then checked  610  whether the MBRS is still switched on. If it is not, the process is stopped. If the MBRS  100  is still on, the process is repeated from the reception of the signal in step  600 . 
     As illustrated in  FIG. 7 , the MBRS  100  may be further simplified by incorporating the antenna selector functionality in the tuning means  700 .  FIG. 7  illustrates a situation where there is no express antenna selector involved. The signal may be received by the external diversity antennas  104 ,  106  and  108  and fed into the detector  116  via the input  110 ,  112  and  114 . As explained above, the detector  116  determines the antenna characteristics and outputs a control signal. The tuning means  700  may receive this control signal and select the required antenna signal for further signal processing. This means that the antenna selection preferably occurs within the tuning means  700 .