DE19927243B4 - receiver - Google Patents

Abstract

A receiver for receiving a multiplex broadcast wave containing broadcast data including a country code, an area code, and a network identification code, comprising:
A receiving means (1 to 5) for changing a receiving frequency,
Demodulation means (6 to 13) for demodulating the broadcast data from a broadcast wave received by the receiving means (1 to 5),
A memory (15) for storing a country code, area code and network code demodulated in the demodulation means (6 to 13) in response to a store instruction,
- comparing means (14) for comparing a demodulated in the demodulating means (6 to 13) country code, area codes and network codes with the country code, the area code and the network code stored in the memory (15), and
A regional switch, which is turned on or off according to an operation,
characterized,
that, when a result of the comparison made by the comparing means (14) indicates that the country code re-demodulated in the demodulating means (6 to 13) and ...

Description

BACKGROUND OF THE INVENTION

 FIELD OF THE INVENTION

The The present invention relates to a receiver capable of to receive a multiplex broadcast wave to which the broadcast information multiplexed.

One Radio Data System (RDS) is as a service for supplying radio listeners with Information related to broadcasting known been. In particular, when broadcasting programs from a Broadcasting station broadcasting information, such as information, which is related to the contents of the programs or the like, sent as data in a multiplexed modulation scheme. On the receiver side the information related to broadcasting is demodulated, so that one radio listeners a desired one based on the demodulated data Select program can.

The Radio data system uses as a secondary carrier 57 kHz, which is the third Harmonic of a 19 kHz stereo pilot signal frequency-modulated from the frequency band Waves out. The secondary carrier is amplitude modulated with a data signal associated with the broadcast related information, such as program content, which have been filtered and double-phase encoded to form a radio data signal to create. The amplitude modulated subcarrier is frequency modulated a main carrier broadcast.

Like it out 1 which shows a base band coding structure of the radio data signal, the radio data signal is repeatedly transmitted in a multiplexed manner with 104 bits as a group. A group has four blocks, each consisting of 26 bits, and each block comprises a 16-bit information word and a 10-bit check word. With regard to the type 0A, as an example, a block 1 is assigned to a program identification code (program identification or PI code) representing a network, a block 2 to a traffic program identification code (TP code) and a traffic announcement code identification or TA code), a block 3 of alternative frequency data (AF data) for a group of network stations broadcasting the same programs, and a block 4 of program service name information data (PS data) as the name a broadcasting station, the name of a network, etc., as in 2 is shown. Each group is also classified by four bits into one of 16 types 0 to 15 according to the contents of the group. There are two versions, A and B, which are defined for each type (0-15). These identification codes are included in block 2. Note that AF data of a network station is sent only in the group of type 0A, while PS data in the group of types 0A and 0B are sent.

Of the Again, PI code consists of a 4-digit hexadecimal value and a 1-digit country code indicating a country, a 1-digit area code, which is a coverage area for broadcast programs in the country, and includes a 2-digit network code which indicates the identifier of a network. The area code is also called a REG code denotes and is set to a respective value of "0" to "F". The REG code equal to "0" indicates that it only there is a single radio station, "1" gives that the same program over countries is broadcast, "2" indicates that the same Program over an entire country is broadcast, and "3" gives that the same surface Program in a relatively wide area, such as a federal state, also aired within a country. The REG code set to "4" - "F" indicates that each Radio station within the same network individually a local one Program radiates. Assuming that, for example, three radio stations belong to the same network, are when the REG code assigned to each of the three radio stations is, in the case that the three broadcasters broadcast the same program for a wide range, set to "3", the REG codes of the three radio stations each on a different Value equal to or greater than "4", such as "4", "5" and "6", set in the case that the three radio stations each have different local programs radiate. It can generally be said that broadcasters, that belong to the same network, the same program for radiate a wide range when their REG codes are "1" - "3" while the local broadcasters belonging to the same network broadcast different programs if their REG codes are equal to "4" - "F". A radio station, can accept the "1" - "F" for the REG code, can programs for a wide range or for radiate a local area so that the REG code, that of the broadcaster is assigned it varies, whether a broadcaster broadcasts program or for one local area is determined. Therefore, the REG code is variable. Of the REG code equal to "0" gives a single Broadcasting station, which forms no network and always has the REG code set to "0".

Assuming that a broadcasting station BSa belonging to a network NW (NW = network) For example, on a first channel of the preset channels of a receiver, a channel calling operation is started when a channel dial belonging to the first channel is operated to listen to a program broadcasted in the network NW. In the channel calling operation, the receiver receives a transmission frequency of the broadcasting station BSa, extracts a radio data signal from a received broadcasting wave, and reads out the PI code within the radio data signal. When all four digits in the read-out PI code match the corresponding digits of a PI code stored in memory for the broadcasting station BSa, the receiver continues the receiving state at the same frequency. In this receiving state, the receiver receives a broadcasting wave from a broadcasting station belonging to the same network NW as the broadcasting station BSa and covering the same area and country as the broadcasting station BSa.

If not all four digits in the PI code fully match the corresponding ones Digits of the stored PI code, it is determined whether the remaining digits of the read PI code with the exception of the REG code to the corresponding digits of the stored PI code for the radio station BSa fit. If the read PI code except the REG code still does not fit, become a search operation or others stored in the memory Frequency data used to change the reception frequency and thus a broadcast wave search operation to search for a new one Radio wave to perform. Then put the receiver in the same way described above, if all four digits in a PI code of a broadcast wave resulting from the broadcast wave search operation to corresponding digits of the PI code stored in the memory for the Radio station BSa fit.

If the PI code except for the REG code to the stored PI code fits, sets in contrast, the receiver the reception state at the current reception frequency, if a REG switch set in this is switched off. The REG switch is turned off by a user's operation, if the REG code is ignored and turned on when the REG code is taken into account becomes. If the PI code except for the REG code is stored to the PI code fits, and the REG switch is turned on, the receiver performs the mentioned above Radio wave search operation by and determines if all four digits in a PI code, one resulting from the broadcast wave search operation Radio wave to corresponding stored in the memory digits of the PI code for the Radio station BSa fit.

at however, the channel polling operation may have the receiver when the REG switch is on, a receive state on a currently received one Do not continue broadcasting wave unless all four digits in match a read PI code from the received broadcast wave to corresponding digits of the PI code stored in the memory for the Broadcasting Station BSa.

For example, a broadcasting station BSa (belonging to a network NW) is set at a frequency of 90 MHz on a first channel of a receiver at a location PA within a range A, as shown in FIG 3 is illustrated. The PI code for the broadcasting station BSa has been stored in a memory. Further, the PI code of the broadcasting station BSa has been set to "C312" for wide-area programs and "C412" for programs directed to a local area. Subsequently, when a channel dial belonging to the first channel is operated on the receiver to listen to a program broadcast in the network NW at a location PB within a region B, the broadcast wave seek operation is started since no broadcast wave is received from the broadcasting station BSa can be. When a broadcasting station BSb (on a frequency of 100 MHz belonging to the network NW is present within the area B, the receiver receives a broadcasting wave from the broadcasting station BSb for checking the PI code due to the broadcasting wave search operation Broadcasting station BSb has been set to "C312" for wide area programs and "C512" for local area programs.

If the PI code for the broadcasting station BSa stored in the memory is "C312", and the in the memory stored PI code for the broadcasting station BSb is also "C312", the receiver holds the Receive frequency to 100 MHz and continuously receives the broadcast wave from the broadcasting station BSb. On the other hand, if in the memory stored PI code for the radio station BSa is "C312" and that in the Memory stored PI code for the radio station BSb is "C512", or if the stored PI code for the broadcasting station BSa is "C412" and the stored one PI code for the broadcaster BSb is "C312" ignored by the receiver the broadcast wave from the broadcasting station BSb and stops the reception frequency 90 MHz corresponding to the broadcasting station BSa, whose broadcast wave can not be received at the PB site.

On the other hand, when the REG switch is turned off, a problem arises in that the receiver can also receive a broadcast wave from a broadcasting station connected to the same network and that has an area code (REG code) different from that which can be found in the stored PI code for the broadcast station BSa. Specifically, with reference to the above example, a PI code set to "C312" for broadcast belonging to the same network can be changed to "C412" or "C512", whereas a PI code, the is set to "C412" or "C512", only to "C312" can be changed. However, even if the REG switch is turned off, even if receiving a broadcast wave from a broadcasting station having a PI code ("C512") which never matches the stored PI code ("C412") in FIG Relationship could sustain the reception of the broadcasting wave.

The DE 41 02 919 A1 relates to a method for selecting a reception frequency in an RDS receiver, which can store frequency and PI data from network stations. The PI data of the currently selected receiving station is compared with the PI data of another network station. If it is determined that only the area codes of the PI data do not match, the other network station that is received and has a different area code is selected as the new receiving station.

The DE 41 02 735 C2 also relates to a method for selecting a reception frequency in an RDS receiver for receiving an RDS broadcast wave. The broadcast wave is superimposed on a number of AF data signals of the same program chain and PI data signals including a region code to switch the reception frequency to another frequency of the same program chain given by the AF data, the reception frequency being based on AF data stored given receiving frequency is switched back when the operator triggers a switch-back command.

The DE 39 28 828 A1 describes an RDS receiver in which other reception frequencies are set and checked for the respective reception quality in the case of a reception failure. The basis for this is a method in which the overall AF list of alternative frequencies consists of a sequence of local sublists from which it can be seen whether the alternative frequency in one transmitter of the same or of an adjacent transmitter region is to be assigned to the same broadcaster.

SUMMARY THE INVENTION

It The object of the present invention is to provide a receiver who is able to receive a radio wave from a selected one Maintain a broadcasting station having a PI code, which differs from one in the receiver stored PI code only in one area code (REG code), provided that the Area code resulting from the received broadcast wave of the selected broadcast station is pulled out in a predetermined relation to the area code in the saved PI code.

The present invention solves this task with a receiver according to the characteristics of claim 1. Advantageous developments are mentioned in the subclaims.

at the recipient of the invention sets the recipient the reception of the radio wave, if the in the newly received Radio wave contained area code and stored in the memory Range code are in such a relationship that the one indicates a wide range and the other a local area indicating what makes it possible is made, a change of stored PI codes for one Radio station suitable for receiving reflect.

at the recipient of the invention sets preferably the recipient the reception of the broadcast wave then continues if the two code areas are equal, if both in the newly received radio wave contained area code as well as stored in the memory Range code a program for specify a local area, which makes it possible to make a change the stored PI code for a broadcasting station suitable for receiving reflect.

SUMMARY THE DRAWINGS

1 shows a base band coding structure for a radio data signal,

2 shows a format for a group of type 0A,

3 FIG. 12 is a diagram for explaining the operation of a receiver when moving from a location PA within a range A to a location PB within a range B; FIG.

4 Fig. 12 is a block diagram illustrating the configuration of an RDS receiver to which the present invention is applied, and Figs

5 FIG. 10 is a flow chart illustrating a channel call operation performed by a pro processor in a controller equipped with the receiver.

DESCRIPTION THE PREFERRED EMBODIMENT

A embodiment The present invention will be described in detail below with reference to the accompanying drawings Drawings described.

4 illustrates the embodiment of an RDS receiver to which the present invention is applied. In the illustrated receiver, a broadcasting wave from a desired broadcasting station is emitted from an antenna 1 received, FM-multiplexed broadcast waves selected and in a Vorfeldeinrichtung 2 converted into an intermediate frequency signal (IF signal). The IF signal becomes an FM detector 4 via an IF amplifier 3 fed. The front facility 2 uses, for example, a scheme of a PLL synthesizer (PLL = Phase Locked Loop), using a PLL circuit comprising a programmable frequency divider and configured such that a division ratio of the programmable frequency divider from a controller 14 , which will be described later, is controlled to execute a station selection operation. A detection output of the FM detector 4 becomes an MPX demodulator circuit 5 (MPX = multiplex) supplied to the output signal of the FM detector 4 in L (left) and R (right) audio signals, when a stereo broadcast wave has been received.

When the detection output of the FM detector 4 through a filter 6 A secondary subcarrier at 57 kHz which is amplitude-modulated with a double-phase coded data signal, ie a radio data signal, in a PLL circuit is passed 7 pulled out and demodulated. The demodulated output becomes a digital (D) PLL circuit 8th and a decoder 9 fed. The D-PLL circuit 8th generates a clock for data demodulation based on the demodulated output from the PLL circuit 7 , The generated clock becomes a gate or gate circuit 10 fed. A synchronization detector 11 generates a synchronization detection signal when it detects that the D-PLL circuit 8th is synchronized, and carries the synchronization detection signal of the gate circuit 10 to. The gate circuit 10 opens in response to the synchronization detection signal. The decoder 9 decodes a double-phase coded data signal, which is the demodulated output of the PLL circuit 7 is, in synchronism with that in the D-PLL circuit 8th generated clock.

Output data of the decoder 9 have a group construction of 104 bits consisting of four 26-bit blocks as shown in FIG 1 is shown, and successively, a group block sync (sync) & error detection circuit 12 fed. The group block sync & error detection circuit 12 performs group block synchronization based on a 10-bit offset word associated with a 10-bit check word of each block, and performs error detection on a 16-bit information word based on the check word. The data subjected to error detection becomes an error correction circuit at the next stage 13 corrected for errors and then the controller 14 fed.

The controller 14 The microcomputer comprising a microcomputer brings together code information in each of the blocks of the radio data successively inputted thereto into groups, ie, radio data information associated with the contents of a program currently being received by a broadcasting station (the aforementioned TA Code, TP code, PI code, AF data, PS data, etc.), and stores the matched code information in a memory 15 , The controller 14 controls a reception frequency data value to determine the division ratio of a programmable frequency divider (not shown) of a PLL circuit which is a part of the front end device 2 forms on the basis of a station selection instruction from an operation unit 16 to perform a station selection operation. The reception frequency data may be, for example, a count of a counter.

The receiver also includes a level detector 17 to receive a received signal level (electric field strength) based on the level of an IF signal in the IF amplifier 3 to detect, and a station detector 18 to detect a received station and thus output a station detection signal when the level of an IF signal in the IF amplifier 3 is equal to or higher than a predetermined level, and if a detection output in the FM detector 4 having a so-called S-curve characteristic falling within a predetermined threshold range. The one from the level detector 17 detected, received signal levels and that of the station detector 18 output station detection signal are both the controller 14 fed.

A channel call operation by the processor of the controller 14 is executed, is determined by an in 5 illustrated flowchart described. It is assumed herein that the frequency of an RDS broadcasting station BSa belonging to a network NW has already been set on a first channel of preset channels of the receiver, and that a user selects a channel selection button corresponding to the first channel at the operating unit 16 has been pressed to listen to a program broadcast in the network NW, causing the channel calling operation to be initiated. It is also assumed that the memory 15 stores a PI code (country code, REG code and network code) and frequency data for the BSa broadcast station.

In the channel polling operation, the processor first tunes a frequency according to that in the memory 15 stored frequency data (step S1). This places the receiver in a receive state at a frequency preset on the first channel. Then, the processor determines whether or not a radio data signal has been extracted from a received signal on the currently received frequency (step S2). If no radio data signal has been extracted, the processor proceeds to step S7 which will be described later to search for a new broadcast wave.

In contrast, when a radio data signal has been extracted, the processor reads a PI code in the radio data signal (step S3) and determines whether all four digits of the read-out PI code correspond to the corresponding digits of the memory in the memory 15 stored PI codes for the broadcasting station BSa fit (step S4). When all four digits of the PI code found in the broadcast wave received on the current receiving frequency are related to the corresponding digits of the one in the memory 15 stored PI codes for the broadcasting station BSa, the processor allows the receiver to continue at the current receiving frequency at a receiving station (step S5). That is, since all four digits of the PI code found in the broadcast wave received at the current reception frequency are related to the corresponding digits of the memory in the memory 15 stored PI codes for the broadcasting station BSa, the receiver has received a broadcasting wave from a broadcasting station belonging to the network NW.

If not all four digits of the PI code found in the broadcast wave received on the current receiving frequency are related to the corresponding digits of that in the memory 15 stored PI codes for the broadcasting station BSa, the processor determines in step S6 whether the three digits of the read-out PI code except the REG code to the corresponding digits of the memory in the memory 15 stored PI codes for the broadcast station BSa fit or not (step S6).

If the three digits of the read PI code except the REG code do not match the corresponding digits of the memory 15 stored PI codes for the broadcasting station BSa, the processor performs a broadcast wave search operation to search for a new broadcast wave (step S7). In the broadcast wave search operation, a station may be selected, for example, using an AF data list for the network NW previously stored in the memory. Alternatively, a search operation may be used to sample a receivable frequency range of the receiver while the output of the station detector 18 is monitored, so that the search operation is stopped when the station detection signal from the output of the station detector 18 is detected.

Of the Processor stops after the execution of Step S7 determines if the receiver has received a new broadcast wave or not (step S8). If the recipient has received a new broadcast wave, the processor returns to step S2 back, to determine if a radio data signal from a received signal at the current reception frequency has been pulled out or not. After that, the ones described above operations repeated.

If the processor determines at step S6 that the three digits of the read-out PI code except the REG code are assigned to the corresponding digits of the memory in the memory 15 stored PI codes for the broadcast station BSa, the processor determines whether one in the operating unit 16 arranged REG switch (not shown) is turned on or not (step S9). The REG switch is turned off when the REG code is ignored and turned on when the REG code is taken into account by an operator's operation. When the REG switch is turned off, the processor proceeds to step S5 where the receiver continues the reception state at the current reception frequency. When the REG switch is turned on, the processor distinguishes the REG code within that in the memory 15 stored PI codes for the broadcasting station BSa (step S10). When the REG code is in a range of "0" to "3", as a result of the discrimination in step S10, it indicates that the PI code stored in the memory for the broadcasting station BSa was set as the broadcasting station BSa a program in this case, the processor proceeds to step S5, at which the receiver continues the receiving state at the current receiving frequency. If the REG code is in a range of "4" to "F", as a result of the discrimination in step S10, it indicates that the PI code stored in the memory for the broadcasting station BSa was set as the broadcasting station BSa a program for a local area, in which case the processor reads the REG code in that case distinguishes PI code (step S11).

If the REG code is in the range of "0" to "3" due to the difference in Step S11, includes the present received broadcasting a program that covers a wide range is directed, and stored in the memory PI code for the broadcasting station BSa was set when the radio station BSa a program for a has broadcast local area, so that the processor to step S5 progresses where the receiver is in the receiving state the current one Receiving frequency continues. If the REG code is in a range of "4" to "F", as a result of the discrimination at step S11, the currently received broadcast wave comprises a program aimed at a local area, and the in the memory was stored PI-code for the broadcasting station BSa set as the broadcasting station BSa a program for a local area has aired. Because the REG codes of the read PI codes and the stored PI code do not match, the processor steps to step S7 to search for a broadcast wave search operation to perform after a new radio wave.

If the recipient at step S8 can not receive a new broadcast wave, it means that the receiver receive no broadcast wave from the broadcasting station belonging to the network NW can, which is set on the first channel, so that the processor on a display, not shown, indicating the fact that the receiver is the new one Can not receive radio wave (step S12).

In the channel calling operation, for example, the broadcasting station BSa belonging to the network NW (at a frequency of 90 MHz) is set to the first channel of the receiver at the location PA in the area A, as in the above-mentioned 3 is illustrated. The PI code for the broadcasting station BSa has been simultaneously stored in a memory. Further, the PI code of the broadcasting station BSa has been set to "C312" for wide-area programs and "C412" for programs directed to a local area. Subsequently, when the user operates a channel dial belonging to the first channel of the receiver to listen to a program broadcast in the network NW at a location PB within a range B, the broadcasting search operation is started at step S7, as a Broadcasting wave from the broadcasting station BSa can not be received. When a broadcasting station BSb (at a frequency of 100 MHz) belonging to the network NW is present within the area B, the receiver receives a broadcasting wave from the broadcasting station BSb for checking the PI code due to the broadcasting wave search operation. The PI code of the broadcasting station BSb has been set to "C312" for programs aimed at a wide area and "C512" for programs directed to a local area.

Under the above conditions, the receiver keeps the reception frequency at 100 MHz and continuously receives the broadcast wave from the broadcasting station BSb when in the memory 15 stored PI code for the broadcasting station BSa is "C312" and the PI code for the broadcasting station BSb currently being received by the receiver at the location PB in the area B to which the receiver has moved is also "C312". On the other hand, if the PI code stored in the memory for the broadcasting station BSa is "C312" and the PI code for the broadcasting station BSb currently being received by the receiver at the location PB in the area B to which the receiver is moving has, "C512", the processor discriminates at step S10 that the REG code is in the memory 15 stored PI code for the broadcasting station BSa is in a range of "0" to "3", indicating that a wide range program is broadcast so that the processor proceeds to step S5, at which the receiver sets the receiving frequency 100 MHz and continuously receives the broadcast wave from the broadcasting station BSb. If in the store 15 stored PI code of the broadcasting station BSa is "C412", and the PI code for the broadcasting station BSb currently being received by the receiver at the location PB in the area B to which the receiver has moved is "C312", In step S11, the processor discriminates that the REG code in the PI code extracted from the received broadcast wave is in a range of "0" to "3", indicating that a wide range program is broadcast, so that the processor proceeds to step S5, in which the receiver keeps the reception frequency at 100 MHz and continuously receives the broadcasting wave from the broadcasting station BSb.

However, if that in the memory 15 stored PI code for the broadcasting station BSa is "C412" and the PI code for the broadcasting station BSb currently being received by the receiver at the location PB in the area B to which the receiver has moved is "C512", At step S11, the processor discriminates that the REG code in the PI code extracted from the received broadcast wave is in the range of "4" to "F", indicating that a local area program is broadcasting so that the processor proceeds to step S7 to perform a broadcast search operation to search for a new broadcast wave.

While in the above embodiment the receiver is provided with the REG switch, the present invention can be applied to any receiver without a REG switch. In such a receiver without a REG switch, if the processor determines at step S6 that the three digits of the read-out PI code except for the REG code correspond to the corresponding digits of the memory in the memory, the processor immediately proceeds to step S10 15 stored PI codes for the radio station BSa fit.

According to the present Invention as described above becomes the reception of the broadcasting wave retain if an area code in a newly received Radio wave is included, and an area code in one Memory is stored in such a relationship that the one indicates a wide range and the other a local area indicating what makes it possible is made, a change a stored PI code for a broadcasting station suitable for receiving reflect. The present This invention is particularly useful in station selection processing To run a preset call takes effect when a recipient is without a REG switch is constructed, or to perform a an AF code using retrace processing.

Claims (3)

A receiver for receiving a multiplex broadcast wave containing broadcast data including a country code, an area code and a network identification code, comprising: - a receiving means ( 1 to 5 ) for changing a reception frequency, - a demodulation means ( 6 to 13 ) for demodulating the broadcast data from one of the receiving means ( 1 to 5 ) received radio wave, - a memory ( 15 ) for storing in the demodulation means ( 6 to 13 ) demodulated country codes, area codes and network codes in response to a store instruction, - a comparison means ( 14 ) for comparing one in the demodulation means ( 6 to 13 ) newly demodulated country codes, area codes and network codes with the country code, the area code and the network code stored in the memory ( 15 ), and - a regional switch, which is turned on or off according to an actuation, characterized in that, if a result of the comparison means ( 14 ) indicates that in the demodulation means ( 6 to 13 ) newly demodulated country code and network code respectively match the country code and the network code stored in the memory ( 15 ) are stored (S6), and the regional switch is turned on (S9), - the receiving means ( 1 to 5 ) continues to receive at a current reception frequency (S5) if in the memory ( 15 ) stored region code code for a local area (4-F; S10) and in the demodulation means ( 6 to 13 ) newly demodulated area code is a code for a wide range (0-3) (S11), - whereas the receiving means ( 1 to 5 ) does not continue to receive at the current receive frequency, if in the memory ( 15 ) stored region code code for a local area (4-F; S10) and in the demodulation means ( 6 to 13 ) newly demodulated area code is a code for a local area (4-F) (S11) different from that in the memory ( 15 ) for a local area (4-F). Receiver according to claim 1, characterized in that, if the result of the comparison ( 14 ) indicates that in the demodulation means ( 6 to 13 ) newly demodulated country code and network code respectively match the country code and the network code stored in the memory ( 15 ) are stored (S6), and the regional switch is turned on (S9), the receiving means ( 6 to 5 ) continues to receive at the current reception frequency (S5) if in the memory ( 15 ) stored area code is a code for the wide range (0-3) (S10). Receiver according to claim 1 or 2, characterized in that the receiving means ( 1 to 5 ) continues to receive at the current reception frequency (S5), irrespective of the state of the regional switch, if the result of the comparison by the comparison means (S5) 14 ) indicates that in the demodulation means ( 6 to 13 ) newly demodulated country code, area code and network code respectively match the country code, the area code and the network code stored in the memory ( 15 ) are stored (S4).