WO1994017609A1 - Television viewer monitoring system - Google Patents

Television viewer monitoring system Download PDF

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Publication number
WO1994017609A1
WO1994017609A1 PCT/CA1993/000012 CA9300012W WO9417609A1 WO 1994017609 A1 WO1994017609 A1 WO 1994017609A1 CA 9300012 W CA9300012 W CA 9300012W WO 9417609 A1 WO9417609 A1 WO 9417609A1
Authority
WO
WIPO (PCT)
Prior art keywords
signal
data
channel
receiver
central location
Prior art date
Application number
PCT/CA1993/000012
Other languages
French (fr)
Inventor
John Barrett Kiefl
Arthur David Milton
Original Assignee
John Barrett Kiefl
Arthur David Milton
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US07/732,929 external-priority patent/US5382970A/en
Application filed by John Barrett Kiefl, Arthur David Milton filed Critical John Barrett Kiefl
Priority to AU33411/93A priority Critical patent/AU3341193A/en
Priority to PCT/CA1993/000012 priority patent/WO1994017609A1/en
Publication of WO1994017609A1 publication Critical patent/WO1994017609A1/en

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04HBROADCAST COMMUNICATION
    • H04H60/00Arrangements for broadcast applications with a direct linking to broadcast information or broadcast space-time; Broadcast-related systems
    • H04H60/35Arrangements for identifying or recognising characteristics with a direct linkage to broadcast information or to broadcast space-time, e.g. for identifying broadcast stations or for identifying users
    • H04H60/38Arrangements for identifying or recognising characteristics with a direct linkage to broadcast information or to broadcast space-time, e.g. for identifying broadcast stations or for identifying users for identifying broadcast time or space
    • H04H60/41Arrangements for identifying or recognising characteristics with a direct linkage to broadcast information or to broadcast space-time, e.g. for identifying broadcast stations or for identifying users for identifying broadcast time or space for identifying broadcast space, i.e. broadcast channels, broadcast stations or broadcast areas
    • H04H60/44Arrangements for identifying or recognising characteristics with a direct linkage to broadcast information or to broadcast space-time, e.g. for identifying broadcast stations or for identifying users for identifying broadcast time or space for identifying broadcast space, i.e. broadcast channels, broadcast stations or broadcast areas for identifying broadcast stations
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04HBROADCAST COMMUNICATION
    • H04H60/00Arrangements for broadcast applications with a direct linking to broadcast information or broadcast space-time; Broadcast-related systems
    • H04H60/35Arrangements for identifying or recognising characteristics with a direct linkage to broadcast information or to broadcast space-time, e.g. for identifying broadcast stations or for identifying users
    • H04H60/38Arrangements for identifying or recognising characteristics with a direct linkage to broadcast information or to broadcast space-time, e.g. for identifying broadcast stations or for identifying users for identifying broadcast time or space
    • H04H60/40Arrangements for identifying or recognising characteristics with a direct linkage to broadcast information or to broadcast space-time, e.g. for identifying broadcast stations or for identifying users for identifying broadcast time or space for identifying broadcast time
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04HBROADCAST COMMUNICATION
    • H04H60/00Arrangements for broadcast applications with a direct linking to broadcast information or broadcast space-time; Broadcast-related systems
    • H04H60/76Arrangements characterised by transmission systems other than for broadcast, e.g. the Internet
    • H04H60/81Arrangements characterised by transmission systems other than for broadcast, e.g. the Internet characterised by the transmission system itself
    • H04H60/90Wireless transmission systems
    • H04H60/91Mobile communication networks
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N21/00Selective content distribution, e.g. interactive television or video on demand [VOD]
    • H04N21/80Generation or processing of content or additional data by content creator independently of the distribution process; Content per se
    • H04N21/81Monomedia components thereof
    • H04N21/812Monomedia components thereof involving advertisement data
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N7/00Television systems
    • H04N7/16Analogue secrecy systems; Analogue subscription systems
    • H04N7/173Analogue secrecy systems; Analogue subscription systems with two-way working, e.g. subscriber sending a programme selection signal
    • H04N7/17309Transmission or handling of upstream communications
    • H04N7/17327Transmission or handling of upstream communications with deferred transmission or handling of upstream communications

Definitions

  • DESCRIPTION TECHNICAL FIELD This invention relates to a system for monitoring an collecting data on audience participation and a device for us in such a system.
  • the invention is especially, but no exclusively, applicable to a system for collecting data on a the viewing habits of television viewers and transmitting the data to a central location.
  • the diaries would be collected usually by mai and would take up to several weeks to process and provide th data to the people conducting the survey. This system wa cumbersome and required considerable effort by the viewe selected. In addition there was a considerable time la between the showing of a program and the determination of th results. For the system to give accurate results, it wa essential that the viewer keeping the diary be able to rea and comprehend fairly complex instructions as well as to kno which station is being watched among the ever increasin number of stations available.
  • the average cable TV subscribe can have 40 or more channels available, and it is increasingl difficult to recognize channels and record them accurately in a diary. While the diary system is still in use today it is the subject of much methodological criticism, especially with the increasing amount of "junk" mail and people being more hesitant to participate in surveys.
  • United States Patent No. 4,566,030- Nickerson et al describes a television viewer data collection system having a remote unit at each viewer location with a viewer control for each television receiver.
  • the viewer control includes a channel selector and the viewer control is wired to either a cable converter or the television receiver and the remote unit.
  • the remote unit includes a clock, a microprocessor and a memory. As the viewer operates the viewer control to turn on the associated television receiver and to select a channel, the time and the selected channel are stored in the memory of the remote unit.
  • the remote unit is connected via a modem to a telephone line.
  • the remote unit initiates a call to a central location and, when a connection is established, the remote unit transmits the data stored in its memory to a central location. It will be seen that this type of television data collection system is a great improvement over much earlier systems. It does not require the viewer to perform the onerous task of making repeated diary entries. It does, however, require equipment to be connected to both the television receiver (or cable converter) and a telephone line.
  • An object of the present invention is to overcome many of the foregoing problems.
  • a portable personal data collection device for use in monitoring audience attention to receivers for receiving broadcast signals from a number of broadcast stations, comprises detector means for providing a station identifier identifying the particular one of said broadcast signals being received by said receiver, a clock for providing a signal representing time, a memory for storing data, a cellular telephone module for communicating with a central location, a control for said cellular telephone module, and a processor means, said processor means being responsive to said signal representing the time and to said station identifier for storing in said memory data comprising the time at the beginning and end of receiving signals from said particular one of said broadcast stations, and the statio identification, said control serving to control operation of said cellular telephone module to transmit to said central location the said data stored in said memory.
  • broadcast is used herein to embrace transmission by cable, or wireless means, including satellite and direct transmission.
  • the control may be responsive firstly to the time signal representing time corresponding to a preselected time for operating the cellular telephone module to call the central location and secondly to communication being established with the central location. Additionally, or alternatively, the control may be responsive to a call initiated from the central location to transmit the data.
  • a data collection device for collecting data on the viewing activity of a person viewing a television receiver capable of being tuned to receive one of a plurality of channels, each channel representing a television signal from a respective one of a plurality of television broadcast stations, the television receiver being operable by means of a remote control for generating at least a channel selection signal.
  • the device comprises detector means responsive to said channel selection signal for providing a station identifier, clock means for providing a time signal representing current time, manual input means for entering a confirmation signal indicating that the viewer is in attendance, processor means responsive initially to said station identifier, said confirmation signal and said clock means for recording said channel and said time signal as representing the time at which said channel was selected and the time at which said selection of said channel was discontinued, and responsive subsequently to said station identifier and said time signal to record changes in the channel to which the receiver is tuned and the times at which such changes occurred.
  • Preferred embodiments of the present invention provide a television viewer monitoring system that need not be wired or connected in any way to a television receiver or to a telephone line.
  • the physical equipment itself consists of a small data collection device that is wireless and portable.
  • the present invention needs only a minimum of attention by the viewer an consequently encourages viewer participation.
  • it is able to provide individual records. That is, the syste of the invention is able to record individually the viewin habits of two or more viewers who watch the same televisio receiver and transmit the individual records to a centra location.
  • Embodiments of the present invention can monitor viewin of television receivers whether in the primary residence, second residence, another household, or in a public place.
  • a viewer can enter the channel being watched with a pushbutto channel input.
  • the personal data mete will have an infrared detector similar to that of th television receiver and responsive to the remote control o the television receiver.
  • the personal data meter may have display which shows, at least, the channel number the persona data meter is recording.
  • the personal data meter may also include an "O.K.” o confirmation button.
  • O.K "O.K.” o confirmation button.
  • the personal data meter could also be responsive to the remote control and be turned on by the remote control, in muc the same way that a cable converter operates. The viewer or respondent would still have to confirm attendance by eithe setting the channel on the personal data meter or by pressin the "O.K.” button.
  • the personal data meter ma also be programmed to turn off after three or four minutes an preferably also programmed so that for a period of severa hours it could only be turned on manually. If the remot control has a mute button, the personal data meter can b arranged to respond to that also. A record of any muting ma be valuable to the people recording viewer habits.
  • the personal data meter als responds to the remote control to change the channel settin it has set into it.
  • the personal data meter records the tim of each channel change and the channel involved.
  • the personal data meter will actuate the cellula telephone module and call a central location.
  • a central location might access the personal data meter b telephone.
  • the persona data meter will transmit the data stored in its memory.
  • embodiments of the invention may provide a system that record the viewing habits of one or more viewers watching the sam television receiver and which transmits the recorde information automatically to a central location.
  • Embodiments of the invention may also provide monitoring system for listeners to radio receivers whic requires no connection to a telephone line.
  • a system for monitoring the tuning o receivers for receiving broadcast signals from a selected on of a number of broadcast stations comprising a personal dat meter for each person using one of the receivers, eac personal data meter having a cellular telephone module, control for the cellular telephone module, a clock providin a signal representing the time, a memory, and a means fo identifying the particular one of the broadcast stations bein received by the receiver, the memory being responsive to th signal representing the time and to the means for identifyin the particular one of the broadcast stations being receive for storing data on the time at the beginning and end, respectively, of receiving signals from the particular one o the broadcast stations, the control for the cellular telephon module being responsive firstly to a signal from the cloc representing a preselected time for calling a preselecte number for a central location for receiving data and secondl to a connection being made with the central location fo transmitting to the central location the stored data.
  • the person meter may be responsive to an inaudible signa transmitted with the signal from the television or radi signal.
  • Information such as station or programme identifier, source of the broadcast, time of day, or other arbitrary dat or query may be added to the signal at its source or at an suitable point prior to transmission.
  • the person meter may be adapted to detect the information and use it appropriately. For example, the person meter may detect an identifier an compare it with the channel selected by the user, manually o via the remote control. Alternatively, the person meter ma be arranged to respond to the identifier to identify th channel or program and record the viewing time withou requiring other inputs except confirmation that the user i present.
  • a method and system of encoding informatio into audio transmissions using a pseudo-random signal t encode the information in such a way that the energy conten of the signal is spread across the audio band.
  • Th information to be transmitted is used to modulate the pseudo- random signal.
  • the resulting modulated pseudo-random signa will be transmitted and resemble noise.
  • the audio signa emitted by the receiver will be monitored and the modulate pseudo-random signal demodulated to extract the information.
  • ther is provided a data collection device for use in monitorin audience attention to receivers for receiving signals from a least one transmission station, the transmitted signals havin an additional signal imposed on the audio signal outside th normal audio range, said additional signal being derived b modulating a pseudo-random digital sequence with th information to be encoded, converting the modulated pseudo random sequence to analogue tones, and mixing the tones wit the transmission signal; said device comprising sound detecto means for receiving an audio signal from said receiver an converting said audio signal into a digital signal, a sequenc generator for generating a pseudo-random sequenc corresponding to the pseudo-random digital sequence modulate with said information, and signal processor means responsiv to said pseudo-random sequence for demodulating said digita signal to extract said information.
  • the modulated pseudo-rando signal is mixed with the regular programme material at a leve that is about 20 to 30 dB below the signal level of th regular program material, yet about 3 to 5 dB above the nois floor of the transmission path.
  • Figure 1 is a block diagram of a system according to the invention showing an arrangement at a remote viewer location
  • Figure 2 is a block diagram showing a personal data mete for recording and transmitting to a central location data o a television viewer's habits;
  • Figure 3 is a front view of a typical personal dat meter
  • Figure 4 is a block diagram showing a system respondin to an additional signal from the television station
  • Figure 5 is a block diagram of a personal data mete which is capable of responding to information encoded int inaudible signals transmitted with the audio signal;
  • Figure 6 is a block diagram of equipment for encoding th information to be transmitted inaudibly.
  • Figure 7 is a flowchart illustrating personal data mete activity
  • Figure 8 is a block diagram showing a personal data mete suitable for recording and transmitting to a central locationo data on a radio listener's habits
  • Figure 9 is a front view of a personal data mete suitable for recording and transmitting data on a radi listener's habits.
  • FIG. 1 there is shown in block for an arrangement, according to the invention, for recording dat on a television viewer's viewing activity.
  • An infrared typ of remote control 10 for controlling, for example, channe selection in television broadcast receiver 15 is shown.
  • Thi type of remote control is well known and it may control othe operational features of television receiver 15 such as, fo example, a mute feature which temporarily switches off th sound in the television receiver 15.
  • the remote control 1 has channel selector means, such as push buttons 11. When a television viewer operates the push buttons 11 to select a channel, the remote control 10 emits an infrared channel selection signal represented by broken lines 12.
  • This infrared signal is detected by an infrared responsive channel selector 14 in television receiver 15 which selects or tunes the desired channel in accordance with the viewer's operation of remote control 10.
  • the channel selection signal may be generated by keying-in a specific channel number or by operating an ' " up/down" key to switch from one channel to the next.
  • the personal data meters 16, 17 and 18 have no wired connection with the television receiver 15, or with the television antenna 20 or with the remote control 10.
  • the personal data meters 16, 17 and 18 are simply placed adjacent the television receiver 15 so that each may receive any infrared signal 12 emitted by remote control 10.
  • the personal data meters 16, 17 and 18 can be "taught", i.e.
  • a personal data meter for example, personal data meter 16
  • the personal data meter 16 includes a infrared detector 21 which receives the infrared signal fro remote control 10 ( Figure 1) .
  • the infrared detector 21 i connected to an input/output (I/O) interface 22 which include various device drivers or circuits for interfacing input an output transducers to a microprocessor 23.
  • I/O input/output
  • the channel selection signa received by infrared detector 21 is decoded by a channel detector (not shown) in the input/output interface 22 t provide a channel identifier signal which is then relayed t the microprocessor 23.
  • the I/O interface 22 is also connected to manual inpu circuitry 24 which includes, among other controls, a manually- operated switch for turning on the personal data meter 16.
  • the interface 22 may include means for turnin on the personal data meter 16 in response to the infrare signal from remote control 10 ( Figure 1) which turns on th television receiver 15 ( Figure 1) .
  • the viewer operates manua input 24 when television receiver 15 ( Figure 1) is firs turned on in order to (a) turn on the personal data meter 1 if it is not turned on by the remote control, and (b) set th channel memory device to the same channel as that to whic television receiver 15 ( Figure 1) is tuned. Either of thes operations generates a confirmation signal to th microprocessor 23 to confirm that the viewer is actuall present and paying attention.
  • a clock 26 provides a time signal t microprocessor 23.
  • An audible warning device 27 such as a buzzer, controlled by microprocessor 23, is actuated if, for example, the manual input 24 is operated to set into processor 23 channel number that is incomplete or non-existent. Th audible warning device 27 may also sound if the personal dat meter has detected that the television remote control has bee operated and the personal data meter has not been initialized, and the viewer's presence confirmed, within a predetermine length of time.
  • the viewer need only turn on the personal data meter 1 and set the channel when the television receiver 15 (Figur 1) is first turned on. Any subsequent channel changes mad using remote control 10 ( Figure 1) will automatically b detected by the personal data meter 16 in response to the sam infrared signal that changes the channel in the television receiver.
  • the personal data meter 16 is powered by a battery (not shown) so that there need be no connections required when it is in use, not even to the household AC supply.
  • the channel detector in interface 22 provides a signal to microprocessor 23 representing the channel of record and microprocessor 23 stores the information in a location in a memory 28, together with data on the beginning time and end time at which the channel was selected by remote control 10 ( Figure 1) or, initially, by manual input to the personal data meter 16 if, for example, the television is already operating when the viewer enters the room.
  • remote control 10 Figure 1
  • the data is stored in memory 28.
  • Each personal data meter 16 has a cellular telephone module 31 with a cellular telephone control and modem 32.
  • a trip control 33 is actuated by a time signal derived from clock 26 and representing a preselected time to transmit data.
  • the trip control 33 actuates cellular telephone control and modem 32.
  • the cellular phone control 32 controls the cellular telephone module 31 and calls a preset number for central location 30.
  • the cellular phone control 32 When communication is established with central location 30, the cellular phone control 32 causes microprocessor 23 to access memory 28 and pass the data stored in memory 28 to cellular phone control and modem 32 and cellular telephone module 31 to central location 30. The data is automatically stored at central location 30. The data from each personal data meter is identified by an identification number associated with that personal data meter and transmitted with the data. When the data has been satisfactorily transferred to the central location 30, a signal from the central location 30 causes microprocessor 23 to clear memory 28 for the storing of new data. If communication is not established with the central location 30, the cellular telephone control 32 will try again after a predetermined interval to establish communication.
  • the time required for a personal data meter to transfer data is relatively short.
  • a typical calling procedure might take of the order of 20 seconds with a few more seconds to ensure that satisfactory communication has been established.
  • Transfer of, say, one kilobyte of data, stored in memory 28 to central location 30 might take of the order of 4 to 5 seconds (2400 baud) .
  • a time of 30 seconds might be involved in a typical transfer.
  • muting of the television sound output by operation of the remote control may be detected by the interface 22 and the information recorded and transmitted along with the channel data.
  • the time will not exceed 60 seconds and it is rarely expected to exceed two minutes.
  • the trip controls for each of the personal data meters might be set to initiate calling one minute apart. For each number available at the central location there could be 60 transfers of data per hour. Limited opportunity for re-dialling when communication is not established on the first try, is provided by either extending the time period for each transfer or by providing a re- dialling window at the end of the transfers. The trip control 33 is set for re-dialling accordingly.
  • the first individual turns on the television receiver, turns on the personal data meter assigned to that individual, and sets the appropriate starting channel into the personal data meter.
  • the second individual who may start viewing after the first but while the first individual is still viewing, turns on the personal data meter assigned to that individual, and sets into that personal data meter the channel currently being watched.
  • the audible warning device 27 is connected to microprocessor 23. If there have been no changes in the channel selector 14 in a long time, for example four hours, the audible warning device 27 is actuated. If the viewer is present, the viewer may terminate the audible warning by re- entering the number of the channel being watched either manually or by an infrared remote control or by pressing an "OK" button. If the viewer is not present or takes no action, the audible warning will continue to sound for a preset time, for example 30 seconds, and then the microprocessor 23 will turn off the personal data meter. Referring now to Figure 3, there is shown a front view of a typical personal data meter, for example personal data meter 16 ( Figures 1 and 2) .
  • the display 25 comprises one side to display time and one side to display the current channel number.
  • An infrared light receiver 38 of infrared detector 21 ( Figure 2) receives and responds to infrared light from a remote control.
  • a name sticker 39 is used to identify the individual to whom the personal data meter is assigned. In order to record data pertaining to the watching of video tapes or the playing of video games, it is desirable to set aside particular channel numbers for each of these activities.
  • a television transmitter 40 broadcasts a television signal via transmitting antenna 41.
  • the television broadcast signal will include an additional signal on the sound carrier as will be described.
  • the television broadcast signal is received by the television antenna 20A coupled to a television receiver 15A having the usual speaker 42.
  • a personal data meter 16A is shown with its associated display 25A, a manual input 24A, and audible warning device 27A shown separated.
  • the television receiver 15A is responsive to an infrared signal (represented by broken lines 12A) from a remote control 10A to turn on the television receiver 15A and to tune the television receiver 15A to desired channels.
  • the personal data meter 16A is responsive to the same infrared signal from remote control 10A to turn on personal data meter 16A and to change the channel numbers recorded by personal data meter 16A in accordance with the channels selected on television receiver 15A. Also, as before, the personal data meter 16A has a manual input 24A which is used when the personal data meter is turned on to either set the channel number indicated on display 25A to be the same as the channel to which television receiver 15A is tuned, or establish that the channel number is correct. An audible warning device 27A is also shown.
  • the personal data meter 16A has, in addition, a sound responsive device or sound detector 43.
  • a sound responsive device or sound detector 43 There is an additional signal introduced onto the sound carrier by the television broadcast transmitter or television station 40. This additional signal is conveniently just outside the audible range, conveniently a sub-audio signal. This additional signal may be continuous or may be transmitted when desired. This additional signal will be generated from speaker 42 on television receiver 15A and will be received by sound detector 43. If, for example, the television receiver is turned on but the personal data meter has, for some reason, not been turned on, personal data meter 16A will be turned on by this signal and the audible warning 27A will sound. If desired, display 25A may also be caused to flash. The viewer must respond with an appropriate input at manual input 24A.
  • FIG. 5 shows a personal data meter 16B similar to that shown in Figure 2 and which is capable of responding to inaudible signals encoded into the transmitted audio using spread-spectrum or "frequency hop" techniques. Before the personal data meter 16B is described, however, encoding of the information into the transmitted audio will be described.
  • a modulation encoder 50 combines the programme and/or station identifier and/or other information to be transmitted to the personal data meter, referred to hereafter as "data", with an internal 20 bits/second clock signal to provide clocked data.
  • the information to be transmitted may comprise a station identifier and time-of-day signal.
  • other arbitrary information may be transmitted, perhaps to identify the programme or broadcaster, or to pose questions to the user about the program content.
  • the amount of information is quite small, of the order of 10 to 200 bits for a unique station identifier and time-of-day. Other fields could be appended as required.
  • a pseudo-random sequence generator 52 supplies a 20 bits/second pseudo-random digital sequence to modulation encoder 52, which combines it with the clocked data to provide a modulated pseudo-random digital signal which it supplies to audio circuit 54.
  • the modulated pseudo-random digital signal comprises 8 bit words at the rate of 20 words per second.
  • the words change pseudo-randomly 20 times per second.
  • the modulated pseudo-random signal is converted into analogue tones by audio circuit 54 which may conveniently comprise an audio accessory card for personal computers, such as that marketed under the trade mark SOUND BLASTER, which include, among other things, an analogue-to-digital converter and the capability of generating up to 256 tones selected by individual ones of the 8 bit words from modulation encoder 50. Hence, 20 times per second, the selected tone will change between discrete values which vary pseudo-randomly.
  • the audio circuit supplies the audio tones a mixer 56 which mixes them with the program audio for broadcast to provide the audio signal to be transmitted. As shown in Figure 6, the audio signal may be passed directly to the transmitter, or recorded for later transmission.
  • the tones are mixed at a level which is about 20 to 30 dB belcw the signal level of the regular program material yet about 3 to 5 dB above the noise floor of the broadcast channel. Because the information is modulated onto the pseudo-random signal, its energy is distributed across the audio range. As a result, the information can coexist in the audio portion of the transmitted signal spectrum yet will not be audible and will not detract from the general audio quality of the transmitted signal.
  • the coded information is transmitted periodically.
  • the period is determined according to the needs of the measuring organization.
  • the repetition rate is determined by the number of bits and the bit rate. In practice, it will typically be in the range of 2 sec. to 15 minutes. This requirement gives quite low bit rates.
  • the sound responsive device 43 comprises a microphone 60 connected by way of an audio circuit 62 to a digital signal processor (DSP) 64.
  • DSP digital signal processor
  • a pseudo-random sequence generator 66 and memory device 68 are shown as separate items connected to the DSP 64. In a practical device, the memory 68 would probably be integral and the pseudo-random sequence would be generated in the DSP 64 using software. In fact, it is likely that, in practice, the DSP 64 and microprocessor 23 will be combined into one device.
  • the audio circuit 62 also may comprise an audio accessory card for personal computers, such as that marketed under the trade mark SOUND BLASTER, and include, among other things, an analogue-to-digital converter.
  • SOUND BLASTER an audio accessory card for personal computers
  • Other parts of the personal data meter 16B will not be described in detail since they correspond to those in Figure 2 and have the same reference numbers.
  • the audio signal from the receiver's loudspeaker 42 ( Figure 4) will be received by microphone 60, converted to a digital bit stream by audio circuit 62 and passed to DSP 64.
  • the bit stream comprises a series of 8 bit words oversa pled at 8 kHz.
  • the DSP 64 repeatedly performs Fast Fourier analysis upon the bit stream to determine the energy content in various predetermined bands within the audio range. The bands correspond to the set of frequencies used in encoding the information as described earlier.
  • the DSP 64 stores the results of the Fast Fourier analysis in its memory 68 for subsequent correlation with the known pseudo-random sequence from generator 66.
  • the pseudo-random sequence will repeat after a predetermined interval. It is not necessary to store results for the entire interval.
  • Enough results should be stored to allow sufficient confidence, statistically, in the correlation performed between the samples and the known pseudo-random sequence.
  • the DSP 64 locks onto data, in particular the transitions between frequencies, and acquires the clock signal embedded. It then extracts the data transmitted in the audio signal and passes it to the I/O interface 22.
  • Such methods of decoding spread spectrum codes are well described in the technical literature and will not be described further here.
  • the DSP 64 uses the information to access memory device 68. For example, if the information is a station identifier, the DSP 64 will determine from memory 68 the particular station and supply it, with the time of day, to microprocessor 26 by way of I/O interface 22.
  • the DSP 64 may also monitor the average level of the audio signal, as contained in the Fast Fourier analysis. This average level can be used to determine, for example, whether or not the sound has been muted. (see steps 75 and 76 of Figure 7.)
  • the decoded information is used by the microprocessor 23 along with other information about the environment to determine what information to save for broadcast measurement purposes. This would normally take the form of a decision tree, where inputs from the keyboard, audio source (level and information) are combined to determine if the viewer is still watching the same program.
  • Figures 7A and 7B are a flowchart depicting such a decision process. Referring to 7A, the sample sequence begins with step 71 in which the microprocessor 23 monitors continuously the I/O interface 22 to detect the station ID and transmitted time. In step 72, the microprocessor 23 compares the detected station ID and transmitted time with those previous entered in memory 28. If the station I/D has changed, in step 73 microprocessor 23 records the new station ID and the time it was received in memory 28.
  • step 74 the microprocessor 23 records the internal time from its own internal clock together with particulars of any event which caused the change, for example operation of one of the manual input push buttons or the infra-red control, or any other event that the person meter is capable of detecting.
  • This data is recorded along with the station ID and the transmitted time in memory 28. Recordal of the two times i.e. that transmitted with the audio signal and that internal to the microprocessor 23, makes it possible to determine whether or not the program is being viewed or listened to at the time of transmission or later, i.e. after recording. Also it enables the transmission time of commercials to be confirmed. If necessary, some of the data will not be recorded in memory or will be erased from memory in order to limit the amount of memory capacity required.
  • step 72 the microprocessor 23 determines that the station ID is the same as previously entered in memory 28, i.e. the result of decision step 72 is negative, in step 75 the microprocessor 23 takes the audio level from I/O interface 22, as detected via the sound detector circuit 43, and in step 76 compares it with the audio level previously recorded. If there has been no change in audio level, the microprocessor 23 returns to step 72. If, however, the audio level has changed, in step 77 the microprocessor 23 seeks to determine the cause.
  • step 77 it gets the infra-red information from IR detector 21 and analyses it to determine whether or not it signifies that the change is due to operation of one of the remote control keys. If so, and decision step 78 is positive, the microprocessor 23 returns to step 73 and records station ID, received time and the internal time. More importantly, in step 74 the microprocessor 23 records the causal event as being operation of the remote control.
  • step 79 the microprocessor 23 scans the personal data meter's keyboard push buttons and in step 80 determines whether or not one of the keys has been depressed signifying either a user request or perhaps a response to a question or prompt from the receiver. If one of the keys has been operated, and the result of decision step 80 is positive, in step 81 the microprocessor 23 determines the key depressed and the time and in step 82 forms an event record. It then returns via loop 83 to step 73 and records the event and time etc. in memory 28.
  • step 84 the microprocessor 23 scans its internal timed event information in step 84.
  • Timed event information is stored in program memory within the microprocessor 23, typically before it is issued to the user, though it could be downloaded from central location 30 or entered manually.
  • the timed event information will include, for example certain questions to be asked at certain times, and the time at which the records are to be transmitted to the central location.
  • decision step 86 the microprocessor 23 will determine whether or not it is time for the user to be asked a question about the program being viewed, and if, so display the question on the display 25.
  • step 88 it may activate the audio warning device 27 to draw the user's attention to the displayed question.
  • step 89 the microprocessor 23 monitors the pushbuttons and determines which ones are operated in answer to the question. It then returns via loop 83 to step 73 to record the resulting information in memory 28 by way of step 73 and 74.
  • decision step 86 will be followed by a further decision step which will determine whether or not the timed event is a call for the personal data meter to transmit the contents of memory 28 to the central location 30. If it is, the microprocessor 23 will initiate a transmission as previously described.
  • the sound responsive device 43 could be built into the person meter using a small DSP which is commercially available, which would simplify transfer of information from the DSP. If desired, however, the DSP could be separate from the person meter and connected by a suitable communication channel, for example an infra-red link.
  • a personal person meter embodying the invention could dispense with the infra-red detector and rely only upon detection of the pseudo-random coded audio signal to determine channel selection, with the user merely inputting whatever response is required, such as confirmation of his/her presence, answers to questions, and so on, by way of the pushbuttons.
  • the information to be encoded could be injected into t e audio signal at various points in the transmission system, including when the program material is being created.
  • a programme or source identifier may be used instead of a station identifier.
  • a television transmitter and receiver are shown, the technique could be applied to radio systems.
  • Embodiments of the invention using pseudo-random coding of monitoring information as described with reference to Figures 5 and 6 are not limited to portable data collection devices.
  • the pseudo-random coding technique could be applied also to fixed or hard-wired data collection devices for audience monitoring.
  • the technique could also be used to monitor programme material, including commercials, using fixed or portable monitoring devices, with no audience input.
  • FIG 8 there is shown in block for a personal data meter 16A suitable for monitoring th listening habits of a radio listener. Because there i normally no infrared remote control for the average radio, th radio listener is required to do more than the televisio viewer.
  • the personal data meter 16A is placed conveniently near the radio used by the listener involved in the monitoring. When the listener turns on the radio, the listener must also turn on the personal data meter 16A and select the same radio station on the channel select memory 45 as that to which the radio is tuned. This selection is made by depressing an appropriate one of the push buttons 46.
  • the push button 46 that is depressed is labelled with the call letters of the radio station, and the display 25A may show the call letters of the station, the operating frequency and any other desired information.
  • Audible warning device 27A is actuated if the listener forgets to depress one of the push buttons 46.
  • FIG 9 is a front perspective view of the radio personal data meter 16A whose circuitry in block form was shown in Figure 8.
  • a name sticker 39 is used to identify the personal data meter being used by a particular individual.
  • the display 25A shows current time and the operating condition, that is "ON "1 or ' " OFF".
  • the push buttons 46 each represent a radio station in the listening area which could be tuned in by the listener using personal data meter 16A.
  • buttons 46C, 46D and 46E which represent location, such as indoors, outdoors, automobile, for example.
  • the personal data meter 16A is battery powered, as are the other personal data meters described. This enables them to be carried anywhere. As long as the personal data meter is in an area where cellular telephone communication is feasible, then the transmitting of recorded data requires no action by the listener or viewer. Unlike prior devices, no wired connections to radio, television receivers or telephone systems is required. It is believed that the preceding description will provide a clear understanding of the invention.
  • An advantage of providing the data collection device with a cellular telephone module is that it permits data to be collected very promptly, enabling statistics to be compiled quickly, for example after a specific program has been transmitted. An advertising campaign could than be modified very quickly in dependence upon the feedback provided in this way. Nevertheless, it is envisaged that embodiments of the invention which respond to the remote control channel selection signal could omit the cellular telephone module. The data could retrieved some other way. Even without the cellular telephone module, such a device has advantages over other devices since it provides automatic capturing of channel changes while requiring a limited manual input to confirm the presence of the user.
  • the device could be modified, primarily by programming of the processor, to collect other kinds of data as well, for example audience reaction to programme or advertisement content, or public opinion polls.

Abstract

In a system for monitoring and collecting data on the viewing habits of television viewers or radio listeners, to enable operators of networks or television stations, programmers and advertisers to determine the numbers of viewers watching particular programs, a portable personal data collection device (16, 17, 18) comprises a detector (21, 43) for providing a station identifier identifying the particular broadcast signal being received by the receiver, a clock (26) for providing a signal representing time, a memory (28) for storing data, a cellular telephone module (31) for communicating with a central location, a control (32) for the cellular telephone module, and a microprocessor (23). The microprocessor stores in the memory data comprising the station identification, and the time at the beginning and end of receiving signals from that station. The control is arranged to control operation of the cellular telephone module to transmit the stored data to the central location. The control may respond firstly to a time signal representing a preselected time for operating the cellular telephone module to call the central location and secondly to communication being established with the central location before transmitting the data. Additionally, or alternatively, the control may respond to a call initiated from the central location to transmit the data. The data collection device may include a detector (21) for detecting a channel selection signal from a television remote control to change the station identifier stored in memory and/or a sound detector (43) for detecting a pseudo-random sequence encoded into the broadcast audio signal and decoding it to drive the station identifier and/or other information such as time of day, polling questions, and so on. Manual inputs, for example pushbuttons, may be provided for confirming that the user is actually in attendance.

Description

TELEVISION VIEWER MONITORING SYSTEM
DESCRIPTION TECHNICAL FIELD: This invention relates to a system for monitoring an collecting data on audience participation and a device for us in such a system. The invention is especially, but no exclusively, applicable to a system for collecting data on a the viewing habits of television viewers and transmitting the data to a central location.
BACKGROUND ART:
It is important to networks, television stations, programmers and advertisers to determine the numbers o viewers watching particular programs. Such information coul be used to determine market share and the ratings o particular programs. Since the beginning of televisio attempts have been made to gather information on the viewin habits of television viewers. The earlier systems were quit simple and included the keeping of a diary by a number o randomly selected viewers. These viewers were asked to ente into their diary a record of the channels viewed and the star time and end time for the viewing of each channel. Sinc diaries are limited to the amount of space that can b provided, viewing records are not very precise and shor intervals of tuning may not even be recorded by the surve respondents. The diaries would be collected usually by mai and would take up to several weeks to process and provide th data to the people conducting the survey. This system wa cumbersome and required considerable effort by the viewe selected. In addition there was a considerable time la between the showing of a program and the determination of th results. For the system to give accurate results, it wa essential that the viewer keeping the diary be able to rea and comprehend fairly complex instructions as well as to kno which station is being watched among the ever increasin number of stations available. The average cable TV subscribe can have 40 or more channels available, and it is increasingl difficult to recognize channels and record them accurately in a diary. While the diary system is still in use today it is the subject of much methodological criticism, especially with the increasing amount of "junk" mail and people being more hesitant to participate in surveys.
Subsequent systems became more efficient and more complex. For example, United States Patent No. 4,566,030- Nickerson et al, issued January 21, 1986, describes a television viewer data collection system having a remote unit at each viewer location with a viewer control for each television receiver. The viewer control includes a channel selector and the viewer control is wired to either a cable converter or the television receiver and the remote unit. The remote unit includes a clock, a microprocessor and a memory. As the viewer operates the viewer control to turn on the associated television receiver and to select a channel, the time and the selected channel are stored in the memory of the remote unit. The remote unit is connected via a modem to a telephone line. At a preselected time the remote unit initiates a call to a central location and, when a connection is established, the remote unit transmits the data stored in its memory to a central location. It will be seen that this type of television data collection system is a great improvement over much earlier systems. It does not require the viewer to perform the onerous task of making repeated diary entries. It does, however, require equipment to be connected to both the television receiver (or cable converter) and a telephone line.
There are many shortcomings in this approach, as a result. The equipment and the installation of the equipment tends to be quite expensive. The system is geared only to measure viewing done in the primary residence of the persons chosen to be in the study. Because of the complexity of recruiting and installing the equipment in each household in the survey, the households are asked to participate in the research for months and on occasion for sometimes more than a year. This means there is a possibility that, among other things, the viewing data can be subjected to certain biases. Other monitoring systems are known, for example only, the systems described in Canadian Patent No. 1,105,128-Thompson, issued July 14, 1981 and in United States Patent No. 4,107,734-Percy et al, issued August 15, 1978. These systems require connection to either the television receiver being monitored, the antenna or cable converter, or a telephone line.
US patent number 4,718,106 ( einblatt) issued January 5, 1988 discloses a portable signal detector which responds to audible signals to record automatically the fact that the carrier of the unit is listening to the station transmitting the audible signals. The system is passive, i.e. requires no direct input from the carrier. A drawback, however, is that the device could be activated without the listener being present or paying attention to the receiver. Moreover, Weinblatt proposes to use an audible signal which could be a distraction.
DISCLOSURE OF INVENTION: An object of the present invention is to overcome many of the foregoing problems.
According to one aspect of the invention, a portable personal data collection device, for use in monitoring audience attention to receivers for receiving broadcast signals from a number of broadcast stations, comprises detector means for providing a station identifier identifying the particular one of said broadcast signals being received by said receiver, a clock for providing a signal representing time, a memory for storing data, a cellular telephone module for communicating with a central location, a control for said cellular telephone module, and a processor means, said processor means being responsive to said signal representing the time and to said station identifier for storing in said memory data comprising the time at the beginning and end of receiving signals from said particular one of said broadcast stations, and the statio identification, said control serving to control operation of said cellular telephone module to transmit to said central location the said data stored in said memory.
For convenience, the term "broadcast" is used herein to embrace transmission by cable, or wireless means, including satellite and direct transmission.
The control may be responsive firstly to the time signal representing time corresponding to a preselected time for operating the cellular telephone module to call the central location and secondly to communication being established with the central location. Additionally, or alternatively, the control may be responsive to a call initiated from the central location to transmit the data.
According to another aspect of the invention, there is provided a data collection device for collecting data on the viewing activity of a person viewing a television receiver capable of being tuned to receive one of a plurality of channels, each channel representing a television signal from a respective one of a plurality of television broadcast stations, the television receiver being operable by means of a remote control for generating at least a channel selection signal. The device comprises detector means responsive to said channel selection signal for providing a station identifier, clock means for providing a time signal representing current time, manual input means for entering a confirmation signal indicating that the viewer is in attendance, processor means responsive initially to said station identifier, said confirmation signal and said clock means for recording said channel and said time signal as representing the time at which said channel was selected and the time at which said selection of said channel was discontinued, and responsive subsequently to said station identifier and said time signal to record changes in the channel to which the receiver is tuned and the times at which such changes occurred. Preferred embodiments of the present invention provide a television viewer monitoring system that need not be wired or connected in any way to a television receiver or to a telephone line. The physical equipment itself consists of a small data collection device that is wireless and portable. It can be carried about the household or elsewhere to record viewing that takes place on any television that the viewer chooses to watch. Typically, all persons in a househol chosen to participate in a research or survey would b provided with a separate data collection device. The present invention needs only a minimum of attention by the viewer an consequently encourages viewer participation. In addition, it is able to provide individual records. That is, the syste of the invention is able to record individually the viewin habits of two or more viewers who watch the same televisio receiver and transmit the individual records to a centra location.
Embodiments of the present invention can monitor viewin of television receivers whether in the primary residence, second residence, another household, or in a public place. A viewer can enter the channel being watched with a pushbutto channel input. For those television receivers with a infrared type of remote control, the viewer is not require to enter the channel being watched. The personal data mete will have an infrared detector similar to that of th television receiver and responsive to the remote control o the television receiver. The personal data meter may have display which shows, at least, the channel number the persona data meter is recording.
The personal data meter may also include an "O.K." o confirmation button. Each time the television receiver i turned on, the viewer turns on the personal data meter an confirms they are in attendance by setting the channel, whic is shown on the display, to the same channel as the channe to which the television set is tuned. If the channel numbe is already the same as the number of the channel to which th television receiver is tuned, the viewer may press the "O.K." button, thereby confirming they are in attendance. If afte a specific time, for example, three or four minutes, th viewer does not confirm attendance as indicated above, the the personal data meter would be programmed to shut off. If the television receiver is responsive to an infrare type remote control which can turn on the television receiver, then the personal data meter could also be responsive to the remote control and be turned on by the remote control, in muc the same way that a cable converter operates. The viewer or respondent would still have to confirm attendance by eithe setting the channel on the personal data meter or by pressin the "O.K." button. In this case, the personal data meter ma also be programmed to turn off after three or four minutes an preferably also programmed so that for a period of severa hours it could only be turned on manually. If the remot control has a mute button, the personal data meter can b arranged to respond to that also. A record of any muting ma be valuable to the people recording viewer habits. Once attendance has been confirmed, the viewer ha nothing further to do. As the viewer operates the remot control to change channels, the personal data meter als responds to the remote control to change the channel settin it has set into it. The personal data meter records the tim of each channel change and the channel involved. At predetermined time set into the program of the personal dat meter, the personal data meter will actuate the cellula telephone module and call a central location. Alternatively, a central location might access the personal data meter b telephone. When a connection is established, the persona data meter will transmit the data stored in its memory. Thus, embodiments of the invention may provide a system that record the viewing habits of one or more viewers watching the sam television receiver and which transmits the recorde information automatically to a central location.
Embodiments of the invention may also provide monitoring system for listeners to radio receivers whic requires no connection to a telephone line.
Thus, according to a further aspect of the invention there is provided a system for monitoring the tuning o receivers for receiving broadcast signals from a selected on of a number of broadcast stations, comprising a personal dat meter for each person using one of the receivers, eac personal data meter having a cellular telephone module, control for the cellular telephone module, a clock providin a signal representing the time, a memory, and a means fo identifying the particular one of the broadcast stations bein received by the receiver, the memory being responsive to th signal representing the time and to the means for identifyin the particular one of the broadcast stations being receive for storing data on the time at the beginning and end, respectively, of receiving signals from the particular one o the broadcast stations, the control for the cellular telephon module being responsive firstly to a signal from the cloc representing a preselected time for calling a preselecte number for a central location for receiving data and secondl to a connection being made with the central location fo transmitting to the central location the stored data.
The person meter may be responsive to an inaudible signa transmitted with the signal from the television or radi signal. Information such as station or programme identifier, source of the broadcast, time of day, or other arbitrary dat or query may be added to the signal at its source or at an suitable point prior to transmission. The person meter ma be adapted to detect the information and use it appropriately. For example, the person meter may detect an identifier an compare it with the channel selected by the user, manually o via the remote control. Alternatively, the person meter ma be arranged to respond to the identifier to identify th channel or program and record the viewing time withou requiring other inputs except confirmation that the user i present. In order for the information to be transmitted i conventional television or radio systems, it must be formatte in such a way that it is not removed by the various filter and does not cause interference, either with other equipmen or with the viewer's or listener's enjoyment of the program. Methods of encoding identification signals into television an radio transmissions are known. For a discussion of som methods and their drawbacks, the reader is directed to U patent number 4,945,412 (Kramer) issued July 31, 1990, whic is incorporated herein by reference. Kramer's preference is to transmit subaudible preamble codes and postamble codes wit a program segment of interest.
According to yet another aspect of the present invention, there is provided a method and system of encoding informatio into audio transmissions using a pseudo-random signal t encode the information in such a way that the energy conten of the signal is spread across the audio band. Th information to be transmitted is used to modulate the pseudo- random signal. The resulting modulated pseudo-random signa will be transmitted and resemble noise. The audio signa emitted by the receiver will be monitored and the modulate pseudo-random signal demodulated to extract the information.
According to still another aspect of the invention, ther is provided a data collection device for use in monitorin audience attention to receivers for receiving signals from a least one transmission station, the transmitted signals havin an additional signal imposed on the audio signal outside th normal audio range, said additional signal being derived b modulating a pseudo-random digital sequence with th information to be encoded, converting the modulated pseudo random sequence to analogue tones, and mixing the tones wit the transmission signal; said device comprising sound detecto means for receiving an audio signal from said receiver an converting said audio signal into a digital signal, a sequenc generator for generating a pseudo-random sequenc corresponding to the pseudo-random digital sequence modulate with said information, and signal processor means responsiv to said pseudo-random sequence for demodulating said digita signal to extract said information.
In preferred embodiments, the modulated pseudo-rando signal is mixed with the regular programme material at a leve that is about 20 to 30 dB below the signal level of th regular program material, yet about 3 to 5 dB above the nois floor of the transmission path.
BRIEF DESCRIPTION OF DRAWINGS: Embodiments of the invention will now be described, b way of example, with reference to the accompanying drawings, in which:
Figure 1 is a block diagram of a system according to the invention showing an arrangement at a remote viewer location;
Figure 2 is a block diagram showing a personal data mete for recording and transmitting to a central location data o a television viewer's habits;
Figure 3 is a front view of a typical personal dat meter;
Figure 4 is a block diagram showing a system respondin to an additional signal from the television station;
Figure 5 is a block diagram of a personal data mete which is capable of responding to information encoded int inaudible signals transmitted with the audio signal;
Figure 6 is a block diagram of equipment for encoding th information to be transmitted inaudibly; and
Figure 7 is a flowchart illustrating personal data mete activity; Figure 8 is a block diagram showing a personal data mete suitable for recording and transmitting to a central locatio data on a radio listener's habits; and
Figure 9 is a front view of a personal data mete suitable for recording and transmitting data on a radi listener's habits.
BEST MODE(S) FOR CARRYING OUT THE INVENTION:
Referring now to the drawings, some of the preferre embodiments of the invention are described in detail below. Referring first to Figure 1, there is shown in block for an arrangement, according to the invention, for recording dat on a television viewer's viewing activity. An infrared typ of remote control 10 for controlling, for example, channe selection in television broadcast receiver 15 is shown. Thi type of remote control is well known and it may control othe operational features of television receiver 15 such as, fo example, a mute feature which temporarily switches off th sound in the television receiver 15. The remote control 1 has channel selector means, such as push buttons 11. When a television viewer operates the push buttons 11 to select a channel, the remote control 10 emits an infrared channel selection signal represented by broken lines 12. This infrared signal is detected by an infrared responsive channel selector 14 in television receiver 15 which selects or tunes the desired channel in accordance with the viewer's operation of remote control 10. The channel selection signal may be generated by keying-in a specific channel number or by operating an '"up/down" key to switch from one channel to the next.
Adjacent the television receiver 15 there are located one or more personal data meters, designated by blocks 16, 17 and 18, which comprise data collection devices for recording data on the viewing activity of respective television viewers. There is a personal data meter for each person who will be viewing a particular television receiver and three are shown (i.e. personal data meters 16, 17 and 18 having blocks labelled PM.l, PM.2 and PM.N) . The personal data meters 16, 17 and 18 have no wired connection with the television receiver 15, or with the television antenna 20 or with the remote control 10. The personal data meters 16, 17 and 18 are simply placed adjacent the television receiver 15 so that each may receive any infrared signal 12 emitted by remote control 10. The personal data meters 16, 17 and 18 can be "taught", i.e. adapted to recognize the different kinds of remote control signal in common usage, in much the same way that some remote controls can be taught signals of other remote controls in a household. Referring now to Figure 2, there is shown, in bloc diagram form, a personal data meter (for example, personal data meter 16) . The personal data meter 16 includes a infrared detector 21 which receives the infrared signal fro remote control 10 (Figure 1) . The infrared detector 21 i connected to an input/output (I/O) interface 22 which include various device drivers or circuits for interfacing input an output transducers to a microprocessor 23. When a particula desired channel is selected, the channel selection signa received by infrared detector 21 is decoded by a channel detector (not shown) in the input/output interface 22 t provide a channel identifier signal which is then relayed t the microprocessor 23. The I/O interface 22 is also connected to manual inpu circuitry 24 which includes, among other controls, a manually- operated switch for turning on the personal data meter 16. Alternatively, the interface 22 may include means for turnin on the personal data meter 16 in response to the infrare signal from remote control 10 (Figure 1) which turns on th television receiver 15 (Figure 1) . The viewer operates manua input 24 when television receiver 15 (Figure 1) is firs turned on in order to (a) turn on the personal data meter 1 if it is not turned on by the remote control, and (b) set th channel memory device to the same channel as that to whic television receiver 15 (Figure 1) is tuned. Either of thes operations generates a confirmation signal to th microprocessor 23 to confirm that the viewer is actuall present and paying attention. A display 25, operated b microprocessor 23 by way of a display driver in interface 22, shows the channel to which the device is set and, if desired, the current time. A clock 26 provides a time signal t microprocessor 23.
An audible warning device 27, such as a buzzer, controlled by microprocessor 23, is actuated if, for example, the manual input 24 is operated to set into processor 23 channel number that is incomplete or non-existent. Th audible warning device 27 may also sound if the personal dat meter has detected that the television remote control has bee operated and the personal data meter has not been initialized, and the viewer's presence confirmed, within a predetermine length of time.
The viewer need only turn on the personal data meter 1 and set the channel when the television receiver 15 (Figur 1) is first turned on. Any subsequent channel changes mad using remote control 10 (Figure 1) will automatically b detected by the personal data meter 16 in response to the sam infrared signal that changes the channel in the television receiver.
Preferably the personal data meter 16 is powered by a battery (not shown) so that there need be no connections required when it is in use, not even to the household AC supply.
The channel detector in interface 22 provides a signal to microprocessor 23 representing the channel of record and microprocessor 23 stores the information in a location in a memory 28, together with data on the beginning time and end time at which the channel was selected by remote control 10 (Figure 1) or, initially, by manual input to the personal data meter 16 if, for example, the television is already operating when the viewer enters the room. However, to avoid recording times for each channel selected when a viewer is scanning through a number of channels, it is desirable not to provide a record of channels selected for less than a preset short time, say for example, five seconds or less. With this exception, the data is stored in memory 28. Preferably, once a day, at a preselected time when it is unlikely there will be much television viewing being recorded, for example between 2 a.m. and 6 a.m., the data recorded in memory 28 is transmitted to a central location 30. Each personal data meter 16 has a cellular telephone module 31 with a cellular telephone control and modem 32. A trip control 33 is actuated by a time signal derived from clock 26 and representing a preselected time to transmit data. The trip control 33, in turn, actuates cellular telephone control and modem 32. The cellular phone control 32 controls the cellular telephone module 31 and calls a preset number for central location 30. When communication is established with central location 30, the cellular phone control 32 causes microprocessor 23 to access memory 28 and pass the data stored in memory 28 to cellular phone control and modem 32 and cellular telephone module 31 to central location 30. The data is automatically stored at central location 30. The data from each personal data meter is identified by an identification number associated with that personal data meter and transmitted with the data. When the data has been satisfactorily transferred to the central location 30, a signal from the central location 30 causes microprocessor 23 to clear memory 28 for the storing of new data. If communication is not established with the central location 30, the cellular telephone control 32 will try again after a predetermined interval to establish communication.
The time required for a personal data meter to transfer data is relatively short. A typical calling procedure might take of the order of 20 seconds with a few more seconds to ensure that satisfactory communication has been established. Transfer of, say, one kilobyte of data, stored in memory 28 to central location 30 might take of the order of 4 to 5 seconds (2400 baud) . Thus a time of 30 seconds might be involved in a typical transfer. There may be more data stored in memory 28 and more time may be required. For example, there may be almost continuous television operation by a viewer with many channel changes. Also, muting of the television sound output by operation of the remote control may be detected by the interface 22 and the information recorded and transmitted along with the channel data. However, in most cases the time will not exceed 60 seconds and it is rarely expected to exceed two minutes. Thus, the trip controls for each of the personal data meters might be set to initiate calling one minute apart. For each number available at the central location there could be 60 transfers of data per hour. Limited opportunity for re-dialling when communication is not established on the first try, is provided by either extending the time period for each transfer or by providing a re- dialling window at the end of the transfers. The trip control 33 is set for re-dialling accordingly.
It will be seen that if there are two personal data meters at a television receiver, each associated with an individual viewer, the first individual turns on the television receiver, turns on the personal data meter assigned to that individual, and sets the appropriate starting channel into the personal data meter. The second individual, who may start viewing after the first but while the first individual is still viewing, turns on the personal data meter assigned to that individual, and sets into that personal data meter the channel currently being watched.
The audible warning device 27 is connected to microprocessor 23. If there have been no changes in the channel selector 14 in a long time, for example four hours, the audible warning device 27 is actuated. If the viewer is present, the viewer may terminate the audible warning by re- entering the number of the channel being watched either manually or by an infrared remote control or by pressing an "OK" button. If the viewer is not present or takes no action, the audible warning will continue to sound for a preset time, for example 30 seconds, and then the microprocessor 23 will turn off the personal data meter. Referring now to Figure 3, there is shown a front view of a typical personal data meter, for example personal data meter 16 (Figures 1 and 2) . The display 25 comprises one side to display time and one side to display the current channel number. Push buttons 35 for channel selection, 36 for on/off switching and 37 for an "OK" button, form the manual input means 24 (Figure 2) . An infrared light receiver 38 of infrared detector 21 (Figure 2) receives and responds to infrared light from a remote control. A name sticker 39 is used to identify the individual to whom the personal data meter is assigned. In order to record data pertaining to the watching of video tapes or the playing of video games, it is desirable to set aside particular channel numbers for each of these activities.
Referring now to Figure 4, another embodiment of the invention is shown. A television transmitter 40 broadcasts a television signal via transmitting antenna 41. In this instance the television broadcast signal will include an additional signal on the sound carrier as will be described. The television broadcast signal is received by the television antenna 20A coupled to a television receiver 15A having the usual speaker 42. A personal data meter 16A is shown with its associated display 25A, a manual input 24A, and audible warning device 27A shown separated. As before, the television receiver 15A is responsive to an infrared signal (represented by broken lines 12A) from a remote control 10A to turn on the television receiver 15A and to tune the television receiver 15A to desired channels. Also, as before, the personal data meter 16A is responsive to the same infrared signal from remote control 10A to turn on personal data meter 16A and to change the channel numbers recorded by personal data meter 16A in accordance with the channels selected on television receiver 15A. Also, as before, the personal data meter 16A has a manual input 24A which is used when the personal data meter is turned on to either set the channel number indicated on display 25A to be the same as the channel to which television receiver 15A is tuned, or establish that the channel number is correct. An audible warning device 27A is also shown.
The personal data meter 16A has, in addition, a sound responsive device or sound detector 43. There is an additional signal introduced onto the sound carrier by the television broadcast transmitter or television station 40. This additional signal is conveniently just outside the audible range, conveniently a sub-audio signal. This additional signal may be continuous or may be transmitted when desired. This additional signal will be generated from speaker 42 on television receiver 15A and will be received by sound detector 43. If, for example, the television receiver is turned on but the personal data meter has, for some reason, not been turned on, personal data meter 16A will be turned on by this signal and the audible warning 27A will sound. If desired, display 25A may also be caused to flash. The viewer must respond with an appropriate input at manual input 24A. If there is no response confirming the presence of the viewer, the personal data meter is programmed to turn off after a short interval and would not be again activated by this additional signal for a period of several hours. While the inaudible signal could be a short burst or take one of the forms disclosed by Weinblatt, supra, and by Kramer, supra, for example, preferred embodiments of the present invention employ spread spectrum techniques. Figure 5 shows a personal data meter 16B similar to that shown in Figure 2 and which is capable of responding to inaudible signals encoded into the transmitted audio using spread-spectrum or "frequency hop" techniques. Before the personal data meter 16B is described, however, encoding of the information into the transmitted audio will be described. As shown in Figure 6, a modulation encoder 50 combines the programme and/or station identifier and/or other information to be transmitted to the personal data meter, referred to hereafter as "data", with an internal 20 bits/second clock signal to provide clocked data. For simply monitoring what is being viewed, the information to be transmitted may comprise a station identifier and time-of-day signal. Of course, other arbitrary information may be transmitted, perhaps to identify the programme or broadcaster, or to pose questions to the user about the program content. Typically, the amount of information is quite small, of the order of 10 to 200 bits for a unique station identifier and time-of-day. Other fields could be appended as required. A pseudo-random sequence generator 52 supplies a 20 bits/second pseudo-random digital sequence to modulation encoder 52, which combines it with the clocked data to provide a modulated pseudo-random digital signal which it supplies to audio circuit 54. The modulated pseudo-random digital signal comprises 8 bit words at the rate of 20 words per second.
Hence, the words change pseudo-randomly 20 times per second.
The modulated pseudo-random signal is converted into analogue tones by audio circuit 54 which may conveniently comprise an audio accessory card for personal computers, such as that marketed under the trade mark SOUND BLASTER, which include, among other things, an analogue-to-digital converter and the capability of generating up to 256 tones selected by individual ones of the 8 bit words from modulation encoder 50. Hence, 20 times per second, the selected tone will change between discrete values which vary pseudo-randomly. The audio circuit supplies the audio tones a mixer 56 which mixes them with the program audio for broadcast to provide the audio signal to be transmitted. As shown in Figure 6, the audio signal may be passed directly to the transmitter, or recorded for later transmission.
The tones are mixed at a level which is about 20 to 30 dB belcw the signal level of the regular program material yet about 3 to 5 dB above the noise floor of the broadcast channel. Because the information is modulated onto the pseudo-random signal, its energy is distributed across the audio range. As a result, the information can coexist in the audio portion of the transmitted signal spectrum yet will not be audible and will not detract from the general audio quality of the transmitted signal.
The coded information is transmitted periodically. The period is determined according to the needs of the measuring organization. The repetition rate is determined by the number of bits and the bit rate. In practice, it will typically be in the range of 2 sec. to 15 minutes. This requirement gives quite low bit rates.
Because the encoded signal is maintained in the audio band of the regular broadcast channel, it will travel from the transmitter to the receiver and be emitted from the loudspeaker in the usual way. Referring again to Figure 5, the sound responsive device 43 comprises a microphone 60 connected by way of an audio circuit 62 to a digital signal processor (DSP) 64. A pseudo-random sequence generator 66 and memory device 68 are shown as separate items connected to the DSP 64. In a practical device, the memory 68 would probably be integral and the pseudo-random sequence would be generated in the DSP 64 using software. In fact, it is likely that, in practice, the DSP 64 and microprocessor 23 will be combined into one device. The audio circuit 62 also may comprise an audio accessory card for personal computers, such as that marketed under the trade mark SOUND BLASTER, and include, among other things, an analogue-to-digital converter. Other parts of the personal data meter 16B will not be described in detail since they correspond to those in Figure 2 and have the same reference numbers.
The audio signal from the receiver's loudspeaker 42 (Figure 4) will be received by microphone 60, converted to a digital bit stream by audio circuit 62 and passed to DSP 64. The bit stream comprises a series of 8 bit words oversa pled at 8 kHz. The DSP 64 repeatedly performs Fast Fourier analysis upon the bit stream to determine the energy content in various predetermined bands within the audio range. The bands correspond to the set of frequencies used in encoding the information as described earlier. The DSP 64 stores the results of the Fast Fourier analysis in its memory 68 for subsequent correlation with the known pseudo-random sequence from generator 66. The pseudo-random sequence will repeat after a predetermined interval. It is not necessary to store results for the entire interval. Enough results should be stored to allow sufficient confidence, statistically, in the correlation performed between the samples and the known pseudo-random sequence. When a sufficiently high correlation factor is achieved, which need not necessarily be unity, the DSP 64 locks onto data, in particular the transitions between frequencies, and acquires the clock signal embedded. It then extracts the data transmitted in the audio signal and passes it to the I/O interface 22. Such methods of decoding spread spectrum codes are well described in the technical literature and will not be described further here.
Where appropriate, before transmitting the data to I/O interface 22, the DSP 64 uses the information to access memory device 68. For example, if the information is a station identifier, the DSP 64 will determine from memory 68 the particular station and supply it, with the time of day, to microprocessor 26 by way of I/O interface 22.
The DSP 64 may also monitor the average level of the audio signal, as contained in the Fast Fourier analysis. This average level can be used to determine, for example, whether or not the sound has been muted. (see steps 75 and 76 of Figure 7.)
The decoded information is used by the microprocessor 23 along with other information about the environment to determine what information to save for broadcast measurement purposes. This would normally take the form of a decision tree, where inputs from the keyboard, audio source (level and information) are combined to determine if the viewer is still watching the same program. Figures 7A and 7B are a flowchart depicting such a decision process. Referring to 7A, the sample sequence begins with step 71 in which the microprocessor 23 monitors continuously the I/O interface 22 to detect the station ID and transmitted time. In step 72, the microprocessor 23 compares the detected station ID and transmitted time with those previous entered in memory 28. If the station I/D has changed, in step 73 microprocessor 23 records the new station ID and the time it was received in memory 28. In step 74 the microprocessor 23 records the internal time from its own internal clock together with particulars of any event which caused the change, for example operation of one of the manual input push buttons or the infra-red control, or any other event that the person meter is capable of detecting. This data is recorded along with the station ID and the transmitted time in memory 28. Recordal of the two times i.e. that transmitted with the audio signal and that internal to the microprocessor 23, makes it possible to determine whether or not the program is being viewed or listened to at the time of transmission or later, i.e. after recording. Also it enables the transmission time of commercials to be confirmed. If necessary, some of the data will not be recorded in memory or will be erased from memory in order to limit the amount of memory capacity required. The microprocessor 23 will then return to step 71 and assume its monitoring or waiting mode. If in step 72 the microprocessor 23 determines that the station ID is the same as previously entered in memory 28, i.e. the result of decision step 72 is negative, in step 75 the microprocessor 23 takes the audio level from I/O interface 22, as detected via the sound detector circuit 43, and in step 76 compares it with the audio level previously recorded. If there has been no change in audio level, the microprocessor 23 returns to step 72. If, however, the audio level has changed, in step 77 the microprocessor 23 seeks to determine the cause. Thus, in step 77 it gets the infra-red information from IR detector 21 and analyses it to determine whether or not it signifies that the change is due to operation of one of the remote control keys. If so, and decision step 78 is positive, the microprocessor 23 returns to step 73 and records station ID, received time and the internal time. More importantly, in step 74 the microprocessor 23 records the causal event as being operation of the remote control.
If decision step 78 indicates that the remote control was not operated, in step 79 the microprocessor 23 scans the personal data meter's keyboard push buttons and in step 80 determines whether or not one of the keys has been depressed signifying either a user request or perhaps a response to a question or prompt from the receiver. If one of the keys has been operated, and the result of decision step 80 is positive, in step 81 the microprocessor 23 determines the key depressed and the time and in step 82 forms an event record. It then returns via loop 83 to step 73 and records the event and time etc. in memory 28.
If no key has been depressed, and the result of decision step 80 is negative, the microprocessor 23 scans its internal timed event information in step 84. Timed event information is stored in program memory within the microprocessor 23, typically before it is issued to the user, though it could be downloaded from central location 30 or entered manually. The timed event information will include, for example certain questions to be asked at certain times, and the time at which the records are to be transmitted to the central location. Thus in decision step 86 the microprocessor 23 will determine whether or not it is time for the user to be asked a question about the program being viewed, and if, so display the question on the display 25. At the same time, in step 88 it may activate the audio warning device 27 to draw the user's attention to the displayed question. In step 89, the microprocessor 23 monitors the pushbuttons and determines which ones are operated in answer to the question. It then returns via loop 83 to step 73 to record the resulting information in memory 28 by way of step 73 and 74.
Although not specifically shown in Figure 7B, decision step 86 will be followed by a further decision step which will determine whether or not the timed event is a call for the personal data meter to transmit the contents of memory 28 to the central location 30. If it is, the microprocessor 23 will initiate a transmission as previously described. The sound responsive device 43 could be built into the person meter using a small DSP which is commercially available, which would simplify transfer of information from the DSP. If desired, however, the DSP could be separate from the person meter and connected by a suitable communication channel, for example an infra-red link.
It is also envisaged that a personal person meter embodying the invention could dispense with the infra-red detector and rely only upon detection of the pseudo-random coded audio signal to determine channel selection, with the user merely inputting whatever response is required, such as confirmation of his/her presence, answers to questions, and so on, by way of the pushbuttons.
It should be appreciated that the information to be encoded could be injected into t e audio signal at various points in the transmission system, including when the program material is being created. In the latter case, a programme or source identifier may be used instead of a station identifier. Also, although a television transmitter and receiver are shown, the technique could be applied to radio systems.
Embodiments of the invention using pseudo-random coding of monitoring information as described with reference to Figures 5 and 6 are not limited to portable data collection devices. The pseudo-random coding technique could be applied also to fixed or hard-wired data collection devices for audience monitoring. The technique could also be used to monitor programme material, including commercials, using fixed or portable monitoring devices, with no audience input.
Referring now to Figure 8, there is shown in block for a personal data meter 16A suitable for monitoring th listening habits of a radio listener. Because there i normally no infrared remote control for the average radio, th radio listener is required to do more than the televisio viewer. The personal data meter 16A is placed conveniently near the radio used by the listener involved in the monitoring. When the listener turns on the radio, the listener must also turn on the personal data meter 16A and select the same radio station on the channel select memory 45 as that to which the radio is tuned. This selection is made by depressing an appropriate one of the push buttons 46. The push button 46 that is depressed is labelled with the call letters of the radio station, and the display 25A may show the call letters of the station, the operating frequency and any other desired information. Audible warning device 27A is actuated if the listener forgets to depress one of the push buttons 46.
It will be seen that whenever the listener wishes to listen to another station, the listener must not only tune the radio receiver to the desired station but must also depress the appropriate one of push buttons 46.
Each of the remaining blocks representing circuitry in Figure 8 operates in the same manner as corresponding blocks in Figure 2 and it is believed no further description is required.
Figure 9 is a front perspective view of the radio personal data meter 16A whose circuitry in block form was shown in Figure 8. A name sticker 39 is used to identify the personal data meter being used by a particular individual. The display 25A shows current time and the operating condition, that is "ON"1 or '"OFF". The push buttons 46 each represent a radio station in the listening area which could be tuned in by the listener using personal data meter 16A. There is a push button 46A that can be pushed when the listener is listening to tapes or CDs or other recordings. There is an "ON/OFF" push button 46B. There are buttons 46C, 46D and 46E which represent location, such as indoors, outdoors, automobile, for example. The personal data meter 16A is battery powered, as are the other personal data meters described. This enables them to be carried anywhere. As long as the personal data meter is in an area where cellular telephone communication is feasible, then the transmitting of recorded data requires no action by the listener or viewer. Unlike prior devices, no wired connections to radio, television receivers or telephone systems is required. It is believed that the preceding description will provide a clear understanding of the invention.
An advantage of providing the data collection device with a cellular telephone module is that it permits data to be collected very promptly, enabling statistics to be compiled quickly, for example after a specific program has been transmitted. An advertising campaign could than be modified very quickly in dependence upon the feedback provided in this way. Nevertheless, it is envisaged that embodiments of the invention which respond to the remote control channel selection signal could omit the cellular telephone module. The data could retrieved some other way. Even without the cellular telephone module, such a device has advantages over other devices since it provides automatic capturing of channel changes while requiring a limited manual input to confirm the presence of the user.
It should be appreciated that the device could be modified, primarily by programming of the processor, to collect other kinds of data as well, for example audience reaction to programme or advertisement content, or public opinion polls.
INDUSTRIAL APPLICABILITY
It will be appreciated that, although the specific embodiment describes a system in which the transmitted signal is broadcast, the invention is not limited to wireless systems, whether satellite or direct transmission systems, but also comprehends cable systems.

Claims

CLAIMS: 1. A system for monitoring audience attention to television or radio transmissions, comprising at least one transmission station (40) for transmitting at least an audio signal including program material and an additional signal, said additional signal being derived by modulating a pseudo¬ random digital sequence with information to be encoded, converting the modulated pseudo-random sequence to analogue tones, and mixing the tones with the audio signal for transmission; said system further comprising at least one receiver for emitting an audio signal including the tones, and a data collection device, said device comprising sound detector means (60,62) for receiving an audio signal from said receiver (15) and converting said audio signal into a digital signal, a sequence generator (66) for generating a pseudo¬ random sequence corresponding to the pseudo-random digital sequence modulated with said information, and signal processor means (64) responsive to said pseudo-random sequence for demodulating said digital signal to extract said information.
2. A system as claimed in claim 1, wherein said tones are mixed with said audio signal at a level which is below a prescribed signal level of regular program material yet above a noise floor of the transmission path.
3. A system as claimed in claim 2, wherein the tones are at a level about 20 to 30 dB below the prescribed signal level of regular program material and about 3 to 5 dB above the noise floor.
4. A data collection device (16A) for use in monitoring audience attention to receivers for receiving signals from at least one transmission station, the transmitted signals having an additional signal imposed on the audio signal outside the normal audio range, said additional signal being derived by modulating a pseudo-random digital sequence with the information to be encoded, converting the modulated pseudo¬ random sequence to analogue tones, and mixing the tones with the transmission signal; said device comprising sound detector means (43; 60,62) for receiving an audio signal from said receiver (15) and converting said audio signal into a digital signal, a sequence generator (66) for generating a pseudo- random sequence corresponding to the pseudo-random digital sequence modulated with said information, and signal processor means (64) responsive to said pseudo-random sequence for demodulating said digital signal to extract said information.
5. A device as claimed in claim 4, wherein the signal processor means (64) is operable to perform Fourier analysis repeatedly upon said digital signal to determine energy distribution in predetermined bands, and to correlate the energy distribution over a predetermined period of time with a pseudo-random sequence corresponding to that modulated by the information.
6. A device as claimed in claim 4, further comprising manual input means, said processor means being operable to detect user operation of the manual input means and to record data in dependence upon both the information and user input.
7. A device as claimed in claim 4, further comprising a cellular telephone module (31) for communicating with a central location (30) and a control (32) for said cellular telephone module, the control being operable by the processor means to operate said cellular telephone module to transmit to said central location the said data stored in said memory.
8. A device as claimed in claim 4, further comprising a detector for detecting signals from a receiver remote control, said processor means being operable to monitor said detector means and to record said data in dependence upon both the information received in the audio signal and operation of said remote control.
9. A system for monitoring audience attention to receivers for receiving broadcast signals from a number of broadcast stations, comprising a portable personal data meter (16, 17, 18) for each person to be monitored attending to one of said receivers, each portable personal data meter having a cellular telephone module (31) for communicating with a central location (30) , a control (32) for said cellular telephone module, a clock (26) providing a signal representing time, a memory (28) for storing data, a detector means (21, 22; 43, 22) for providing a station identifier identifying the particular one of said broadcast stations being received by said receiver, and a processor means (23) , said processor means being responsive to said signal representing the time and to said station identifier for storing in said memory data comprising the time at the beginning and end of receiving signals from said particular one of said broadcast stations, and the station identification, said control serving to control operation of said cellular telephone module to transmit to said central location the said data stored in said memory.
10. A system as claimed in claim 9, wherein said control for said cellular telephone module is responsive firstly to a signal from said clock representing a predetermined time for calling a preselected number for a central location for receiving data, and secondly to a connection being made with said central location to initiate transmission of said data.
11. A system as claimed in claim 9, wherein said control for said cellular telephone module is responsive to a request in a call initiated by said central location to transmit said data.
12. A system as claimed in claim 9, for monitoring the viewing activity of television viewers at a plurality of remote locations and transmitting data relating to the viewing activity to a said central location, each said receiver comprising a television broadcast receiver (15) having a viewer-operated remote control (10) for generating at least a channel selection signal for selecting a desired one of said plurality of television broadcast channels, each said detector means of a said personal data meter comprising a detector (21) responsive to said channel selection signal for providing a station identifier identifying the channel to which the said television receiver is tuned, said processor unit (23) being operable to record in said memory (28) the channel identifier and period for which such channel was selected.
13. A system as claimed in claim 12, wherein each said personal data meter comprises a manual means (24) for entering the number of the channel corresponding to the desired channel number to which said television receiver is tuned, and said processor (23) is operable to detect correspondence between the channel identified by means of the station identifier derived from the remote control signal and the channel identification entered manually and commence recording said data when they correspond.
14. A system as claimed in claim 13, wherein each said personal data meter further comprises a warning device (27) and said processor means is operable to operate the warning device if such correspondence is not detected within a predetermined time interval after the personal data meter has been turned on.
15. A system as claimed in claim 12, wherein each said personal data meter further comprises a manual input means (24, 37) operable by the user to provide a confirmation signal confirming presence and attention to the receiver, and a warning device (27) , said processor means being operable to operate said warning device in the absence of such confirmation signal within a predetermined time interval.
16. A system as claimed in claim 9, in which the broadcast signal from said selected one of said broadcast stations has an additional signal imposed on the sound carrier outside the normal audio range, and in which each said personal data meter further comprises a sound detector for said additional signal, and a warning device, said processor being responsive to said additional signal for energizing said warning device requiring manual input from a respective one of said persons and, on receipt of such manual input, commencing recording of said data.
17. A data collection device for use in monitoring audience attention to receivers for receiving broadcast signals from a number of broadcast stations, said device comprising a portable personal data meter comprising a cellular telephone module (31) for communicating with a central location, a control (32) for said cellular telephone module, a clock (26) providing a signal representing time, a memory (28) for storing data, a detector means (21, 22; 43, 22) for providing a station identifier identifying the particular one of said broadcast stations being received by said receiver, and a processor means (23) , said processor means being responsive to said signal representing the time and to said station identifier for storing in said memory data comprising the time at the beginning and end of receiving signals from said particular one of said broadcast stations, and the station identification, said control serving to control operation of said cellular telephone module to transmit to said central location the said data stored in said memory.
18. A device as claimed in claim 17, wherein said control for said cellular telephone module is responsive firstly to a signal from said clock representing a predetermined time for calling a preselected number for a central location for receiving data, and secondly to a connection being made with said central location to initiate transmission of said data.
19. A device as claimed in claim 17, wherein said control for said cellular telephone module is responsive to a request in a call initiated by said central location to transmit said data.
20. A device as claimed in claim 17, for monitoring the viewing of a television broadcast receiver having a viewer- operated remote control for generating at least a channel selection signal for selecting a desired one of said plurality of television broadcast channels, said device comprising a detector responsive to said channel selection signal for providing a said station identifier identifying the channel to which the said television receiver is tuned, said processor being operable to record in said memory the channel identifier and period for which such channel was selected.
21. A device as claimed in claim 20, further comprising manual input means (10, 35) for entering the number of the channel corresponding to the desired channel number to which said television receiver is tuned, and wherein said processor is operable to detect correspondence between the channel identifier derived from the remote control signal and the channel identification entered manually and commence recording said data when they correspond.
22. A device as claimed in claim 21, further comprising a warning device (27) and wherein said processor means is operable to operate the warning device if such correspondence is not detected within a predetermined time interval after the personal data meter has been turned on.
23. A device as claimed in claim 20, further comprising a manual input means (37) operable by the user to provide a confirmation signal confirming presence and attention to the receiver, and a warning device, said processor means being operable to operate said warning device in the absence of such confirmation signal within a predetermined time interval.
24. A device as claimed in claim 17, for monitoring a 5 receiver responsive to a broadcast signal from said selected one of said broadcast stations having an additional signal imposed on the sound carrier outside the normal audio range, said detector means comprising a sound detector for said additional signal, and a warning device, said processor being 10 responsive to said additional signal for energizing said warning device and requiring manual input from a respective one of said persons and, on receipt of such manual input, commencing recording of said data.
15 25. A device as claimed in claim 17, for monitoring a receiver responsive to a broadcast signal from said selected one of said broadcast stations having an additional signal imposed on the sound carrier outside the normal audio range, wherein said additional signal comprises a pseudo-random
20 sequence modulated with information to be communicated to the personal data meter, said detector means comprising a sound detector means for receiving audio from said receiver and converting said audio into a digital signal, a sequence generator for generating a pseudo-random sequence
25 corresponding to the pseudo-random sequence modulated with said information, and signal processor means responsive to said pseudo-random sequence for demodulating said digital signal to extract said information.
30 26. A device as claimed in claim 24, for monitoring the viewing activity of a television viewer at a remote location and transmitting data relating to the viewing activity to a said central location, each said receiver comprising a television broadcast receiver (15, 15A) operable by means of
35 a viewer-operated remote control for generating at least a channel selection signal for selecting a desired one of said plurality of television broadcast channels, said detector means in said device being responsive to said channel selection signal for providing said station identifier.
27. A data collection device for collecting data on the viewing habits of a person viewing a television receiver (15,
15A) capable of being tuned to receive one of a plurality of channels, each channel representing a television signal from a respective one of a plurality of television broadcast stations, the television receiver being operable by means of a remote control (10, 10A) for generating at least a channel selection signal, the device comprising detector means (21) responsive to said channel selection signal for providing a station identifier, clock means (26) for providing a time signal representing current time, manual input means (24) for entering a confirmation signal indicating that the viewer is in attendance, processor means (23) responsive initially to said station identifier, said confirmation signal and said clock means for recording said channel and said time signal as representing the time at which said channel was selected and the time at which said selection of said channel was discontinued, and responsive subsequently to said station identifier and said time signal to record changes in the channel to which the receiver is tuned and the times at which such changes occurred.
28. A device as claimed in claim 27, further comprising audible warning signal generating means (27) operable in the event that said confirmation signal is not received within a predetermined time elapsed from initial channel selection.
29. A data collection device for collecting data on the listening habits of a person using said data collection device and listening to one of a plurality of radio signal broadcasting stations, and for transmitting collected data to a central location, comprising means (46) for receiving a manual input representing said one of a plurality of broadcasting stations and providing a signal representing the respective broadcast station, a clock means (26A) for providing a time signal, memory means (28A) , a processor (23A) for receiving said time signal and said signal representing the respective broadcast station and storing in said memory means data representing the start time and the stop time for listening to said respective broadcast station, a cellular telephone module (31A) , and a control (32A) for said cellular telephone module, said control being operable to cause the cellular telephone module to transmit to said central location the said data stored in said memory.
PCT/CA1993/000012 1991-07-19 1993-01-19 Television viewer monitoring system WO1994017609A1 (en)

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US07/732,929 US5382970A (en) 1991-07-19 1991-07-19 Television viewer monitoring system including portable data meter for each viewer
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