DE29908045U1 - Wireless transmission device with a speaker system - Google Patents

Description

1
Wireless transmission device with a loudspeaker system

The present innovation relates to a wireless transmission device with a loudspeaker system, in particular a wireless transmission device with a loudspeaker system, which can transmit audio signals simultaneously from a left (L) and a right (R) audio channel via different channels to a loudspeaker for the purpose of emitting sounds.

Figure 1 shows a wireless transmission device with a loudspeaker system according to the prior art with a transmission unit 80 and a reception unit 90. In the transmission unit 80, the audio signals of the left (L) and right (R) are modulated by means of a multiplexer 81. The modulated signal is then sent to an antenna 83 by means of a transmission module for radio frequencies in order to be radiated from there.

The receiving unit 90 receives the signal from the transmitting unit 80, forwards the received signal to a demultiplexer 93 via a radio frequency receiver module 92 for demodulation so that the original left and right audio signals are obtained again.

Accordingly, the purpose of the present innovation is to create a wireless transmission device with a loudspeaker system in which the right/left audio signals are detected by a microprocessor, which then controls the frequency of the radio frequency channel and which determines the left and right audio frequencies of the receiving and transmitting ends. Furthermore, the purpose of the present innovation is to create a wireless transmission device with a loudspeaker system in which the creation of an excessively high level of the audio signal is prevented. The sound quality should not be influenced by environmental influences.

Further various tasks and advantages of the present innovation are immediately apparent from the following

detailed description together with the attached drawings. They show:

Figure 1 is a circuit block diagram of a wireless transmission device with a loudspeaker system according to the prior art.

Figure 2 shows a circuit block diagram of the transmission device according to the present innovation, Figure 3 shows the circuit of the transmission device according to the present innovation;

Figure 4 shows the circuit block diagram of the circuit unit in the receiver unit of the present innovation; Figures 5 and 6 show the circuit diagrams of the receiver unit according to the present innovation; Figures 7 and 8 show flow charts of the internal program of the microprocessor in the receiver unit of the present innovation.

0 The wireless transmission device with a loudspeaker system according to the present innovation is explained in more detail with reference to Figures 2 to 6. The wireless transmission device contains a loudspeaker system with a loudspeaker, a transmission unit 1, a reception unit 2, and at least one loudspeaker 3.

The transmission unit 1 is formed by a voltage supply 11, a voltage regulator 12, a microprocessor 13, a radio frequency transmission module 14, a level control circuit 15 and a transmitting antenna 16.

The power supply 11 (adapter) serves to pass on its output voltage to the voltage regulator 12 in order to supply it (12) with the necessary working voltage.

The voltage regulator 12 is formed by a voltage regulator circuit Ul, a switch Sl,

Resistors R12, Rl and R4, capacitors Cl, C2, C3, C4 and C5, a light-emitting diode LEDl, a Zener diode, ZD5, a diode and other components. Its output is connected to the microprocessor 13 and the radio frequency transmission module 14.

The voltage regulator 12 serves to regulate the output voltage of the power supply 11 in order to obtain a direct voltage of V in order to supply the microprocessor 13 and the radio frequency transmission module 14 with the necessary working voltage.

The radio frequency transmission module 14 is formed by connecting a modulator circuit T1, a connector strip CN1 and other parts together. Its input is connected to a level control circuit 15, formed from the resistors R9 and R10, a variable resistor VR1, capacitors CI1 and C12, diodes D1 and D4, Zener diodes ZD1 to ZD4 and other components, whereby the variable resistor VR1, the diodes D1 and D4, the Zener diodes ZD1 to ZD4 are designed as a blocking circuit. The blocking circuit is used to limit the level in order to avoid an excessively high audio output level and to achieve a required protective effect. The output of the modulator circuit T1 is connected to a transmitting antenna 16.

The microprocessor 13 is formed by an integrated circuit U2, resistors R2, R3, R5, R6, R7, RIl, capacitors C9, ClO, C13 etc. Data lines SCL, SDA and a control line EN of the integrated circuit U2 are connected to the radio frequency transmission module 14. The inputs/outputs of the microprocessor 13 are connected to a switch S2, via which four channels can be selected.

The microprocessor 13 causes the switch S2 to switch to a selected channel so that the radio frequency transmission module 14 receives the input audio signal of the

different channels and then transmits the modulated signal via the transmitting antenna 16.

In Figures 4 and 5, the receiving unit 2 is formed from a voltage supply 21, a voltage regulator 22, a microprocessor 23, a radio frequency receiving module 24, a display for the reception strength of the input signal 25, a receiving antenna 26 and an amplifier 17.

The power supply 21 (adapter) serves to supply its output voltage to the voltage regulator 22 and the amplifier 27 in order to supply the voltage regulator 22 and the amplifier 27 with the necessary working voltage.

The voltage regulator 22 is formed from a voltage regulator circuit Ul, a switch Sl, resistors Rl, R2, capacitors Cl, C2, C3, C4, C5, a light-emitting diode LED2, a Zener diode ZDL, a diode Dl and other components. Its output is connected to the microprocessor 23 and the 0 radio frequency reception module 24.

The voltage regulator 22 serves to regulate the output voltage (15 V DC) of the power supply 21 in order to derive a DC voltage of 5 V therefrom in order to supply the microprocessor 23 and the radio frequency reception module 24 with working voltage.

The radio frequency reception module 24 is formed from a modulator circuit C2, a connector strip CN3 and other 0 components. Its input is connected to the receiving antenna 26. Its output is connected to a variable resistor VR which controls the volume. The variable resistor VR is connected to an amplifier 27 formed from a circuit U4, transistors Q1 and Q2, resistors R40 to R54, capacitors C40 to C51 and other parts. The amplifier output is connected to the loudspeaker 3.

The microprocessor 23 is formed by a circuit U3,

Resistors R3 to R8, capacitors C9 to Cl0 and other components. It is connected to the radio frequency receiving module 24 by means of data lines SCL, SDA and a control line 231 (EN). The line 232 for muting is connected to the amplifier 27. The inputs/outputs of the microprocessor 2 3 are connected to switches S4 and S5. The switch S4 has 4 channels, while the switch S5 is used to select the right/left audio signal.

With the help of the internal program, the microprocessor determines

23 the switch positions of the switches S4 and S5, controls the frequency of the radio frequency channel for a "right or left audio channel" decision of the receiving or transmitting ends. The radio frequency receiving module then receives the signals from the receiving antenna 26 and demodulates them.

The demodulated signals are then sent to amplifier 2 for amplification. Finally, loudspeaker 3 emits the corresponding sounds.

0 In addition, a reception strength indicator 25 for the received signal (RSSI) is connected between the radio frequency reception module

24 and the microprocessor. The reception strength indicator

25 for the received signal is made up of operational amplifiers U4A and U4B, resistors R11 to R14, capacitors C14, C15, C17 etc.

The reception strength indicator 25 for the received signal derives a signal from the radio frequency reception module 24 that indicates the field strength of the carrier signal. This signal is used to determine the sound quality influenced by environmental factors. If the quality of the audio signal is poorer than a predetermined value, the microprocessor 23 mutes the loudspeaker 3.

5 Figure 7 shows a flow chart of the program stored in the microprocessor 23 of the receiving unit 2 of the present innovation. First, it is determined whether the frequency is 900 MHz or 863 MHz (step 50).

If the frequency is 863 MHz, the indicator is set to 863 MHz (step 501) and the frequency is clamped (step 51). If the frequency is '90'(T MHz, the indicator is set to 900 MHz (step 502) and the frequency is clamped (step 51). Then it is checked whether the channel has been changed (step 52).

If not, this detection process continues, otherwise it is determined whether the channel is a transmit channel or a receive channel (step 53).

If the channel is a transmit channel, the left audio channel address 531 is read and the read data is sent to a channel change subroutine of the program to perform an action. After performing the action, the right audio channel address 533 is sent to the channel change subroutine to perform a necessary action. After this action, the process returns to step 52. If the channel is a receive channel, the process determines whether it is a left or right channel (step 54).

If the channel is a right channel, the process reads a received address 541 for the right audio channel and transfers the read data to the channel change subroutine to perform the corresponding action. After completing this action, the process returns to step 52. If the channel is a left channel, the process reads the received address 542 of the left audio channel and transfers the read data to the channel change subroutine to perform a necessary action 0. After this action, the process returns to step 52.

Figure 8 shows a flow chart for channel switching. First, the method determines whether the selected channel is the first channel (step 70).

If yes, it is determined whether the frequency of the channel is 900 MHz or 863 MHz (step 73). Otherwise, the address

incremented by 3 (step 701). It is then determined whether the selected channel is the second channel (step 71).

If yes, the process continues at step 73. Otherwise, the address is incremented by 3 (step 711). Then it is determined whether the selected channel is the third channel (step 72).

If yes, the process goes to step 73. Otherwise, the address is incremented by 3 (step 721). Then it is determined whether the frequency of the channel is 900 MHz or 863 MHz (step 73).

If the frequency is 863 MHz, the value 4OH is added to the address in step 731. Then, any value of the address table is read (step 732). Otherwise, if the frequency is 900 MHz, any value in the address table is read directly (step 732). Then, data corresponding to the address value is sent to the radio frequency receiving part 24 (step 733). Then, the process returns to the main program.

Therefore, by means of the special circuit arrangement described above using wireless transmission, the incoming signals from the left (L) or right channel (R) are divided into different channels and transmitted to the loudspeaker 3 for sound emission. An excessively large sound input signal is avoided and the sound quality is unaffected by the external environment.

Although the present invention has been described with respect to the preferred embodiments, it is to be understood that the invention is not limited to the details described. Various alternatives and modifications have been suggested in the foregoing description and others will be apparent to one skilled in the art. Therefore, all such alternatives and modifications are within the scope of the present invention, as

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8 it is defined in the appended claims

Claims (9)

9 Protection claims 1. Wireless transmission device with a loudspeaker system with the following features: 5 at least one loudspeaker (3), a transmission unit (1) for simultaneously transmitting audio signals of a left (L) and a right (R) audio channel via different channels of a receiving unit (2), the receiving unit (2) comprising: - an input voltage supply to supply the receiving unit (2) with working voltage, - a receiving antenna (26) for receiving the signal from the transmission unit (1) - a radio frequency receiving module (24) connected to the receiving antenna (26) and whose output is connected to an amplifier (27), the output of the amplifier (27) being connected to the loudspeaker (3), - a microprocessor (23) connected to the radio frequency receiving module (24) and correspondingly to the amplifier (27), the inputs/outputs of the microprocessor (23) being connected to a first (S4) and a second switch (S5), the first switch (S4) being able to select a channel 5 from a number of selectable channels and the second switch (S5) being used to select the right/left audio frequency, the microprocessor (23) determining the states of the first (S4) and the second switch (S5), controlling the frequency of the audio frequency channel and determining the left or right audio channel from the receiving and transmitting ends, the radio frequency receiving module (24) receiving signals from the receiving antenna (26) is demodulated, whereby the amplifier (27) subsequently amplifies these signals and then sends them to the loudspeaker (3) for transmission, and - with a reception strength indicator (25) for the reception signal, which is connected between the radio frequency reception module (24) and the microprocessor (23), whereby the reception strength indicator (25) for the reception signal is a 10 derives a signal indicating the field strength of the carrier signal from the radio frequency receiving module (24), whereby the sound quality influenced by environmental factors is determined and the microprocessor (23) mutes the loudspeaker (3) if the sound quality is too poor. 2. Wireless transmission device with a loudspeaker system according to claim 1, in which the input voltage supply further comprises a voltage supply (21), the output of which is connected to the amplifier (27) and a voltage regulator (22), in which the voltage regulator (22) serves to regulate the voltage received from the voltage supply (21) in order to generate a voltage therefrom and to use this to supply the microprocessor (23) and the radio frequency reception module (24) with the necessary working voltage. 3. Wireless transmission device with a loudspeaker system according to claim 1, wherein the microprocessor (23) is connected to the radio frequency receiving module (24) by means of data lines SCL, SDA and a control line EN (231). 4. Wireless transmission device with a Loudspeaker system according to claim 1, wherein the microprocessor (23) is connected to the amplifier (27) via a line (232) for muting. 5. Wireless transmission device with a loudspeaker system according to claim 1, in which a regulating element (VR) is connected between the radio frequency receiving module (24) and the amplifier (27). 6. Wireless transmission device with a loudspeaker system according to claim 1, in which the transmission unit (1) comprises the following features: an input voltage supply for providing working voltage required by the transmission unit (1) will, *"■ a radio frequency transmission module (14) connected to the input voltage supply, the output of which is given to a transmitting antenna (16), with a microprocessor (13) connected to the input voltage supply and, accordingly, to the radio frequency transmission module (14), the input/outputs of which are connected to a third switch (S2) for selection for a plurality of selectable channels, wherein the microprocessor (13) controls the signal frequency of the radio frequency according to the state of the third switch (S2), wherein the radio frequency transmission module (14) modulates the input audio signal and wherein the modulated signal is radiated by the transmitting antenna (16). 7. Wireless transmission device with a loudspeaker system according to claim 6, wherein the transmission unit (1) further comprises a level control circuit (15) which is connected to the input of the radio frequency transmission module (14), the level control circuit (15) serving to receive the audio frequencies of the left (L) and the right channel (R) and to avoid an excessive audio signal level. 8. A wireless transmission device with a speaker system according to claim 6, wherein the input power supply further comprises a power supply (11) whose output is connected to a voltage regulator (12), the voltage regulator (12) serving to regulate the voltage output from the power supply (11) to output a voltage which serves as a working voltage required by the microprocessor (13) and by the radio frequency transmission module (14). 9. Wireless transmission device with a loudspeaker system according to one of claims 1 to 8, in which the microprocessor (13) is connected to the radio frequency transmission module (14) via data lines SCL, SDA and a control line EN.