NL1006403C2 - Method, device and / or system for sending and / or receiving digital information. - Google Patents

Description

METHOD, APPARATUS ΕΝ / OR SYSTEM FOR TRANSMITTING ΕΝ / OR RECEIVING DIGITAL INFORMATION

The present invention provides a system for sending and receiving digital audio information vice versa, the system comprising: - a transmitter; and 5 - a receiving device comprising a personal computer provided with digital storage means.

Such a system is known from US patent US-A-5 550 982, in which a receiving device is provided with a so-called audio play back, which is connected to a server device via a local area network. This known system is particularly suitable for supporting video applications.

This known system has the drawback that it is not possible to transmit pre-recorded audio information in real time without loss of quality.

The present invention aims to enable real-time transmission over a public network of audio information without loss of quality due to repeated compression.

This object is achieved in that the transmitting device comprises at least one audio card to which a microphone can be connected, the audio card comprising an analog / digital converter, a digital / analog converter, and a compression unit for encoding the audio information, that the receiving device is provided with ISDN means for connection to an ISDN line to the transmitting device and that the receiving device is provided with a program routine for enabling a real time transmission of audio information.

1006403 2

The equipment required for the system of the present invention may be of standard manufacture, while a single digital information device of different format will suffice. Furthermore, it is possible in a relatively simple manner to enclose additional information with the audio information according to the system according to the present invention, as well as editing of that digital information.

The present invention further provides a method for transmitting audio information between the transmitting device and the receiving device, and vice versa, wherein at least the receiving device comprises a personal computer, which is provided with digital storage means, characterized in that a microphone obtained analog audio information and an analog / digital converter to digital audio information is converted into an audio card of the transmitter, which audio information is then encoded by a compression unit 20 of the audio card, and that via ISDN- means of the receiving device the digital audio information is received from the transmitting device, the receiving device including a program routine for real time transmission of the digital audio information.

The present invention will be elucidated with reference to the following description of a preferred embodiment thereof, with reference being made to the annexed drawings, in which: Fig. 1 shows a diagram of a preferred embodiment of the present invention; FIG. 2 is a more detailed schematic of the schematic of FIG. 1; Fig. 3 is a diagram for explaining the system schematically shown in Figs. 1 and 2; FIG. 4 is a flow chart of an operation of the system shown in FIGS. 1, 2 and 3; 1006403 Fig. 5 is a flow chart of a detail of Fig. 4; FIG. 6 is a flow chart of a detail of FIG. 5; Fig. 7 shows a detail of the flow chart of Fig. 4; Fig. a shows a detail of the flow chart of Fig. 4; Fig. 9 is a flow chart of a detail of the flow chart of Fig. 4; Fig. 10 is a flow chart of a detail of the flow chart of Fig. 4; Fig. 11 is a flow chart of a detail of the flow chart of Fig. 4; Fig. 12 is a flow chart of a detail of the flow chart of Fig. 4.

A preferred embodiment of a system 1 (fig. 1) comprises a personal computer 2, preferably with a 486 processor or higher, which includes an analog audio board 20 of known design, which has an analog input 4, an analog output 5 and a digital output 6. The audio card 3 is provided with an analog / digital converter 7, a digital / analog converter 8, a compression unit 9 for encoding e.g. 35 according to MPEC-25 layer 2 and a conversion unit 10 for conversion from digital to digital. On a digital storage, for example a hard disk 11, the signal encoded for the first time according to MPEG layer 2 is stored in a section schematically indicated by 12.

On the receiving side there is also a personal computer 22 of the type 486 or higher and an audio card 23 with similar parts as audio card 3. The PC 22 is also provided with a storage 24, eg in the form of a hard disk, which can communicate with the hard disk 11 via a computer network, modem, an ISDN line or a floppy disk, as schematically indicated by block 25. In the figure, scheme 1006403 is also indicated section 26, in which also the the first encoded digital signal is recorded.

For comparison with the present invention, figure 2 shows an existing system, which consists of two so-called dedicated devices 30 and 31, which are provided with a telephone dialer and which can communicate with each other via a public ISDN network, schematically with 32 and 32 resp. 33. The telephone dialers are indicated with 33 resp. 34. Such systems are increasingly being used to broadcast locally made sound recordings, eg from an interview or the like.

In Figure 2, AD denotes an analog digital conversion, with DA digital / analog conversion, with C a compression step, with ED an original digital signal according to MPEG II layer 11 and with NOD a non-original digital signal according to MPEG layer II, that is, after decompression and recompression. You indicate the linear decompression from digital 20 to digital.

Without going into further detail on existing systems, such as those marketed by the applicant eg under the name Digicorder, it is clear that in certain circumstances quality loss occurs through the digital decompression step, or via transmission via the public network 32 either through the respective digital outputs 35, 36.

Figure 3 shows a diagram of the present invention, in which a dedicated device 30 'is connected via a network 41 to a personal computer 42, which is provided with a digital storage such as a hard disk 43 and which is provided with an ISDN card 44, as it is commercially available.

45 schematically denotes the software of the system according to the present invention.

i 1 0064 Ü3 5

The ISYS software uses a compression algorithm to transmit good quality audio over the ISDN line. In this preferred embodiment, use is made of the MPEG standard, 5 where the user of the software is able to change certain settings, such as the number of bits per second (bitrate), eg from 32 kbit per second, which produces the audio card, the number of samples per second of the audio signal, from 16 kHz, the recording mode, mono, 10 stereo or joint stereo, where in the case of stereo and joint stereo the bitrate doubles, the header bits of the digital data to be transmitted, and / or an analog / digital input signal. Furthermore, it is also possible to use algorithms other than MPEG, eg G.711 and G.722.

Because a standard computer is used in the system according to the present invention, which is then provided with the software, the equipment can also be used for other purposes, such as the Internet, editing audio using the audio card, word processing , planning, etc. Existing prior art hardware is only suitable for audio transmission. The ISYS software can select and send audio files digitally recorded and stored without the loss of quality outlined above with reference to Fig. 2 occurring.

The operation of the software will be further elucidated with reference to Figures 4-12. At the start of a live recording 50, it is first checked at 51 whether the connection has been made. In the negative case, recording and / or rinsing is stopped at 57 at 57 and the software is put into idle state at 58. In the affirmative case, starting is started at 52, and 53 is checked to see if the connection is present. At 54, play is activated, 35 at 55 the recording and at 56 the ISDN connection.

At 51 (Fig. 5) the number of channels required is determined. First, the number is set to 0 at 61, then the required number at 62 1 00 64 J 3 6 is determined from the bit rate divided by the number 64, after which a channel connection is made at 63. At 64 it is checked whether it is actually present, after which at channel 65 the channel counter 1 is increased. At 66 it is checked whether the number is already sufficient, and in the negative case the loop is repeated. 67 returns, either after the connection is made at 68, or at 69 after the connection is not made.

The enable play 54 (Fig. 6) begins with determining whether an audio frame has been received. If it is determined at 72 that no previous frames were received, the play timer is activated at 73. If it is determined at 74 that the play timer is active, then at 15 75 it is checked whether 12 milliseconds have elapsed. The play timer is stopped at 76, and playback starts at 77. Then at 78 a frame is sent to the audio card, after which it returns to the main program at 79.

Activating recording 55 (Fig. 7) begins by determining whether an audio frame has been recorded at 81, then inverting the bit order of each bit in the frame at 82. At 83, the frame is sent via ISDN, and at 84 returns to the main 25 program.

When activating the ISDN according to 56 (Fig. 8), it is determined at 85 whether data has been received, after which, at 86, data is copied to a buffer. At 87 the frame is read, while at 88 it returns to the main program.

A frame is read according to 87 by, as indicated in fig. 9, determining at 91 whether audio has been found, at 92 determining whether a header has been found, and performing a check at 93, after which at 94 it is determined whether a frame has been received and is ready to be played so that it can return at 95.

1006403 7

Whether according to 91 has been found (Fig. 10) is determined by determining whether according to the MPEG standard from a position 0 determined at 102 or fourteen ones have been found at this level (FF F in 5 hexadecimal notation). As long as at 103 that the position is determined to be smaller than the bytes in the buffer, and at 104 to determine that the position is greater than 0, steps 105, 106, and 107 determine whether the current byte is unequal to OxFF and whether the previous byte 10 is equal to 0xFF, after which it is determined at 109 that audio has been found, while returning at 111. When the position in the buffer equals 0, at 112 the value of the previous byte is made equal to 0x00 because no previous byte exists. At 110, it is determined that no audio has been found, while at 111 it returns. At 112, the value of the previous bite is determined.

Whether according to 92 has been found (Fig. 11) is determined by determining whether according to the MPEG standard 20 from the position found in Fig. 10, or at this level fourteen ones have been found (FF F in hexadecimal notation). As long as at 113 that the position is determined to be less than the number of bytes in the buffer, the number of ones is determined per byte. At 114, the position of the byte is determined, while at 115, the position in the byte, the bit position, is determined. Since a byte consists of eight bits, it is determined at 116 whether the position in the byte is less than eight. If the position is greater than or equal to eight, then in 120 the next byte is jumped to, and returns to 113. As long as the position is less than eight, it is determined at 117 whether the current position in the byte is one. If there is a one at that position, at 118 the number of ones increases by one, and at 119, and jumps to the next position in the byte. Then it returns to 116. When at 117 it is determined that there is no one, at 121 it is determined whether the 1 η n rί n s 8 number of ones is greater than or equal to fourteen. If fewer than 14 ones have been counted, it will jump to 119 and count the ones from the current position. When 121 determines that fourteen or more ones have been counted consecutively, 122 determines whether the position in the byte is greater than or equal to six. If so, 123 decreases the current position in the buffer by one. If not, at 124 the current position 10 in the buffer is decreased by two. According to the MPEG standard, the fourteen ones must always start at the beginning of a byte. This means that the position in the byte (the bit position) must be equal to 0. To achieve this, it is determined in 125 how many steps all 15 bits have to be shifted to get the first one at position in the byte. At 126 it is determined that an audio header has been found. When it is determined at 113 that the end of the buffer has been reached, it is determined at 127 that no audio header has been found. At 128 20 is returned.

Whether according to 93 a frame is complete and playable (fig. 12) is determined by checking at 129 whether all the necessary bytes for a frame are present. If not, 134 25 determines that the frame is incomplete and returns 135. When it is determined at 129 that the frame is complete, it is determined at 130 whether all bits should be shifted (how much all bits should be shifted is determined in Fig. 11). If 30 by 130 is determined to shift the bits, it is done at 131. At 132, it is checked whether the first four bytes of the header conform to the MPEG standard. If these bytes are good, at 133 it is determined that the frame is playable and it returns at 135.

Otherwise, at 134 it is determined that the frame is not playable and it returns at 135.

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Claims (7)

System for sending and receiving digital audio information, the system comprising: - a transmission device; and - a receiving device comprising a personal computer provided with digital storage means, characterized in that the transmitting device comprises at least one audio card to which a microphone can be connected, wherein the audio card is provided with an analog / digital converter, a digital / analog converter, 10 and a compression unit for encoding the audio information, that the receiving device is provided with ISDN means for connection to an ISDN line to the transmitting device and 15 that the receiving device is provided with a program routine to enable real time transmission of audio information. System according to claim 1, wherein the software routine is able to keep track of whether a connection has been made, is able to activate 'PLAY', registration and / or ISDN transmission. System as claimed in claim 1 or 2, wherein the transmitting device is provided with storage means. System according to claim 2 or 3, wherein a subroutine 'activate play' of the routine checks whether audio frames have been received. System according to any one of claims 1-4, wherein an 'activate record' subroutine of the software routine checks whether an audio frame is registered and, in the affirmative case, sends a frame via an ISDN line to the receiving device. The system of any one of claims 2-5, wherein an 'activate ISDN' subroutine of the 1006403 software routine includes a 'read frame' subroutine for checking whether audio has been found and whether a header has been found. 7. Method for transmitting audio information between the transmitting device 5 and the receiving device, and vice versa, wherein at least the receiving device comprises a personal computer, which is provided with digital storage means, characterized in that analog signals obtained from a microphone audio information and an analog-to-digital converter to digital audio information is converted into an audio card of the transmitter, which audio information is then encoded by a compression unit of the audio card, and which is provided via ISDN means of the receiver the digital audio information is received from the transmitter, the receiver including a program routine for real time transmission of the digital audio information. 1006403