WO2005041051A2 - Data transmission system, digital signal processing device and method for transmitting a data signal - Google Patents

Abstract

The invention relates to a data transmission system (1), a digital signal processing device configured as a master station (2) and a method for transmitting a data signal (27). The invention is characterized in that the following steps are carried out in order to transmit a data signal (27) between a first digital signal processing device that is configured as a master station (2) and at least one second digital signal processing device (7) selected from amongst a plurality of digital signal processing devices that are configured as slave stations (7, 10, 13) and that are connected to the master station (2) by means of at least one data bus (19): (A) transmission of a clock signal (28) to the at least one selected slave station (7); (B) transmission of the data signal (27) synchronous to the clock signal (28) via the data bus (19), wherein only the slave station (7) receiving the clock signal (28) receives or sends the data signal (27).

Description

description

Data transmission system, digital signal processing device and method for transmitting a data signal

The invention relates to a data transmission system for transmitting a data signal between a plurality of digital signal processing devices, a digital signal processing device which is designed as a master station and a method for transmitting a data signal.

Such a data transmission system, as well as such a digital signal processing device and a corresponding one

Methods are known for example from US 4,689,740. Data transmission between digital signal processing devices from one master station to several slave stations is described there. The digital signal processing device that supplies a clock signal is called the master station, and the digital signal processing device that receives the clock signal is called the slave station. Since more than one slave station is connected to the master station, the problem of addressing the correct slave station for data transmission is solved by giving each slave station an individual address. After recognizing your own addressing, the selected slave station is ready to receive data. All other slave stations ignore the transmitted data. However, complex and complex circuits are necessary both on the master station and on the slave stations in order to code or decode this individual addressing.

No. 5,327,121 describes addressing the slave stations via a line which is present separately for each slave station. The object of the present invention is to present a data transmission system, a digital signal processing device and a method which enable simplified circuits on master and slave stations.

According to the invention, the object is achieved by a data transmission system for transmitting a data signal between a plurality of digital signal processing devices, in which at least (A) a first digital signal processing device, which is designed as a master station, has at least (a) a first master clock output, ( b) a second master clock output and (c) a master data bus connection, (B) a second digital signal processing device which is designed as a first slave station, which (a) has a slave clock input and (b) has a slave Data bus connection, (C) a third digital signal processing device which is designed as a second slave station, which (a) has a slave clock input and (b) a slave data bus connection, (D) a data bus consisting of one or more Data lines connecting the master data bus connection with the slave data bus connections, (E) a first clock line connecting the first mast he clock output connects to the slave clock input of the first slave station and (F) a second clock line is provided which connects the second master clock output to the slave clock input of the second slave station.

The invention is based on the finding that at least two slave stations can also be addressed via clock lines with the aid of a clock signal, whereby only the slave stations that are to be addressed receive a clock signal. For this purpose, the slave stations each have their own clock line, which they connect to the master station. The clock lines are therefore not designed in the form of a bus structure which simultaneously feeds a clock to all slave stations. Since the clock signal is used for addressing and not addressing, so that coding and decoding of addressing can be omitted, the circuits on both the master and slave stations are relatively simple and less complex than in known masters - and slave stations.

In addition, the effective bandwidth of the data line, i.e. the bandwidth that is provided for the transmission of user data is fully utilized, since no bandwidth is lost through address information, the so-called “protocol overhead”.

Alternatively, it is known to use so-called “chip select” lines for addressing slave stations, which are provided as additional lines in addition to the clock and data lines, and each from the master station to each slave station A “chip select” line has the function of a switch which, in order to address a slave station, feeds a signal, for example a 1, to a slave station and thereby activates it. However, these additional lines also necessitate additional pins, which one generally wants to save in the case of increasingly complex semiconductor chips. In addition, the routing of the lines between the chips becomes more complex the more lines are necessary. The data transmission system according to the invention therefore saves one pin on each slave station and master station in comparison.

In a further development of the data transmission system according to the invention, a large number of further clock lines are provided, each clock line being exactly one connects another master clock output of the same master station with exactly one slave clock input to one slave station from a large number of other slave stations. This ensures that each slave station receives its own clock line, which connects it to the master station, so that several slave stations can be addressed simultaneously using clock signals without the need for complicated circuits or an additional "protocol overhead""that reduces the effective bandwidth of the data signal.

Furthermore, the object is achieved by a digital signal processing device, which is designed as a master station, which has at least (A) a master data bus connection, for connecting a data bus, (B) a large number of master clock outputs, for connecting a large number of clock lines , - (C) a selection device for selecting at least one of the master clock outputs for outputting at least one clock signal and (D) a transmission device which transmits a data signal to the data bus via the master data bus connection in synchronism with the clock signal.

The digital signal processing device according to the invention makes it possible to design master and slave stations which do not require a complicated circuit for coding or decoding an address. It even enables simultaneous addressing of at least two slave stations that are connected in parallel to the master station via a data bus, a selection device, typically a digital circuit, controlled by, for example, a processor, microcontroller or a CPU (central processor Unit = central processor unit), which selects the corresponding master clock output via which a clock signal is sent to the slave stations. Synchronously to this, a transmitting device sends a data signal via the Data bus, whereby only the slave stations receive the data signal, which receive a clock signal synchronously with it.

In a further development, the digital signal processing device according to the invention, which is designed as a master station, has a receiving device which receives a data signal from the data bus via the master data bus connection in synchronism with the clock signal. In synchronism with the clock signal, the receiving device, typically a digital circuit, receives a data signal via the data bus, only the slave stations transmitting the data signal, which receive a clock signal from the master station in synchronism therewith.

The digital signal processing device, which is designed as a master station, can therefore both send and receive data. If the data bus consists of at least two data lines, the master station can even send and receive at the same time, with at least one data line connecting the receiving device via the master data bus connection to the slave station and at least one further data line connecting the transmitting device via the master data bus connection the slave station.

The object is further achieved by a method for transmitting a data signal between a first digital signal processing device, which is designed as a master station, and at least one selected second digital signal processing device, from a multiplicity of digital signal processing devices, which are designed as slave stations, and the can be connected to the master station via a data bus, with the following steps: (A) transmission of a clock signal to the at least one selected slave station, (B) synchronous transmission of a data signal to the clock signal via the data bus, only the slave -Station receives the data signal which receives the clock signal. The inventors have recognized that by addressing at least one slave station with the aid of the clock signal, it is possible to dispense with complicated and complex circuits, as are required when coding and decoding addressing. This means that only the slave station receives a data signal that receives a clock signal at the same time. The decision whether a addressed slave station should receive data can be regulated by a higher-level protocol. In particular, the well-known server-client protocol offers itself, in which the clients, here the slave stations, the server, here the master station, only send data if the latter has previously requested them.

In an advantageous embodiment of the method according to the invention, for the simultaneous transmission of a data signal from the master station to at least two slave stations, at least two clock signals are fed to the slave stations in synchronism with the data signal. In this way, for example, two slave stations can be addressed by the master station at the same time. If several clock signals are output by the master station, those slave stations that receive the clock signals can receive a data signal. All slave stations can be addressed at the same time.

The object is further achieved by a method for transmitting a data signal between a first digital signal processing device, which is designed as a master station, and at least a selected second digital signal processing device, from a multiplicity of digital signal processing devices, which are designed as slave stations, and the can be connected to the master station via a data bus, solved with the following steps: (A) transmission of a clock signal to the at least one selected slave station, (B) Synchronous transmission of a data signal via the data bus to the clock signal, only the slave station transmitting the data signal receiving the clock signal. Here, too, there is no coding and decoding of an addressing, so that the master station and the slave stations can be designed without the circuits required for this.

In a so-called half-duplex transmission, the master station can send data over the data bus to the selected slave stations at a certain point in time and receive data over a data bus from a selected slave station at another point in time.

However, if the data bus consists of at least two data lines, the master station can send data to the selected slave stations via at least one data line of the data bus and receive data from a selected slave station via the at least one other data line of the data bus. So-called full duplex transmission between the master station and a selected slave station is possible.

The transmitting device and the receiving device of the master station can accordingly simultaneously send or receive data via the master data bus connection via respectively assigned data lines of the data bus. An exemplary embodiment of the invention is explained in more detail below with reference to the drawings. Show it

1: a data transmission system according to the invention, FIG. 2: a time flow diagram for the data transmission system according to the invention.

1 shows a schematic representation of the data transmission system 1 according to the invention for serial data transmission between digital signal processing devices. A first digital signal processing device functions here as a master station 2, which supplies clock information, the rest as first, second and third slave stations 7, 10,

13. These are on the one hand, parallel to each other, over one

Data bus 19, on the other hand connected via clock lines 16, 17 and 18 to the master station 2.

The data bus can consist of only a single data line, or also of several data lines, for example two, eight, sixteen or thirty-two, which connect the master station 2 with the slave stations 7, 10, 13. A large number of transmission modes, for example full-duplex, half-duplex or simplex transmission, as well as serial or parallel data transmission can thus be made possible.

The master station 2 contains a master data bus connection 3, a first master clock output 4, a second master clock output 5 and a third master clock output 6. The slave stations 7, 10 and 13 each contain a slave data bus connection 8, 11 and 14 and a slave clock input 9, 12 and 15 each.

Each slave station 7, 10 and 13 thus contains exactly one slave clock input 9, 12, 15. The master station 2 contains the same number of master clock outputs 4, 5, 6 as slave stations 7, 10, 13 are provided.

To connect the slave stations 7, 10, 13 to the master station 2 via the data bus 19, the master data bus connection 3 is on the master station 2 side and the slave data bus connection 8 is on the first slave station 7 On the side of the second slave station 10, the slave data bus connection 11 and on the side of the third slave station 13, the slave data bus connection 14 is provided.

In the case of data transmission from the first master station 2 to, for example, the first slave station 7, a clock signal is sent to the first slave station 7 via the first clock line 16, which enables the latter to receive data. The data are now transmitted synchronously with this clock signal, the first slave station 7 receiving and processing them. The remaining slave stations 10 and 13 do not receive a clock signal, so that they ignore the data that are also received by them.

In addition, for example, data transmission from the first slave station 7 to the master station 2 only takes place when the slave station 7 receives a clock signal.

Possible uses are for micro-controller modules that have to exchange data with peripheral components. One or more master stations are integrated in the micro-controller module, the master stations being able to be controlled by a micro-controller or CPU. The peripheral components usually have a slave station integrated in each case, the slave stations being able to be connected to a master station, as described in FIG. 1.

For example, in the field of mobile radio, the first master station 2 can be integrated on a baseband chip (micro-controller module) and operate the slave stations on the peripheral components. Peripheral components can e.g. Represent modules for voltage regulation (Power Management IC), an HF chip, a Bluetooth chip, a display or a camera.

In addition, a variety of other digital

Signal processing devices, which act as master or slave stations, are contained in the data transmission system 1, the master station 2 having a further master clock output for each additional slave station which is connected to the master station 2.

2 shows a time flow diagram for the transmission system according to the invention, on the basis of which the transmission principle according to the invention is explained in more detail. The timing diagram shows a first time interval

24, a second time interval 25 and a third

Time interval 26 of a data and clock transmission between a master station and two slave stations, with a data signal 27 and a first clock signal 28 for the first

Slave station and a second clock signal 29 for the second

Slave station.

The data signal 27 is transmitted in all three time intervals 24, 25, 26. The master station sends e.g. all connected slave stations have the same data signal 27. In addition, the data signal 27 can also be sent from a slave station to the master station.

If the first slave station is to receive or send the data signal 27, the master station merely sends it a clock signal 28, shown in the first time interval 24. The transmission of the data signal 27 begins with the first rising edge 23 of the first clock signal 28 and ends with each rising edge 30. With each rising edge 23, data (individual bits) are transmitted again, in synchronism with the clock signal 28. Data reception or the sending of data from the first slave station ends when there is no longer a rising edge 23 of the clock signal 28 Will be received.

The second clock signal 29 for the second slave station is linear in this first time interval 24 or shows no alternating edges. Although the data signal 27 is also fed to the second slave station, it is not ready to receive and process this data signal 27. In addition, the second slave station does not send a data signal in this time interval 24.

In contrast, the second receives in the second time interval 25

Slave station receives a second clock signal 29 and synchronously receives or sends data signal 27. In this second time interval 25, the first slave station does not receive a clock signal 28 that has alternating edges and reacts therefore neither on the data signal 27, nor sends it

Data signal to the master station.

In the third time interval 26, the master station sends clock signals 28, 29 to both slave stations, the first clock signal 28 to the first slave station and the second clock signal 29 to the second slave station. The clock signals 28, 29 become synchronous with these the data signal 27 transmitted via the data bus and fed to the slave stations. This enables both slave stations to receive the same data at the same time.

It is also possible, but not shown, that in the time interval 26 a data signal is simultaneously transmitted from the master station to a slave station and a data signal is sent from another slave station to the same master station.

LIST OF REFERENCE NUMBERS

1 data transmission system

2 master station / first digital signal processing device

3 Master data bus connection

4 First master clock output

5 Second master clock output

6 Third master clock output 7 First slave station / second digital signal processing device

8 slave data bus connection

9 slave clock input

10 Second slave station / third digital signal processing device

11 Slave data bus connection

12 slave clock input

13 Third slave station / fourth digital signal processing device 14 Slave data bus connection

15 slave clock input

16 First clock line

17 Second clock line

18 Third clock line 19 Data bus

23 'Rising edge

24 First time interval

25 Second time interval

26 Third time interval 27 Data signal

28 First clock signal

29 Second clock signal

30 descending flank

Claims

claims

1. Data transmission system (1) for transmitting a data signal (27) between several digital signal processing devices with at least:

(A) a first digital signal processing device, which is designed as a master station (2), ^■ at least (a) a first master clock output (4), (b) a second master clock output (5) and (c) one Master data bus connection (3),

(B) a second digital signal processing device which is designed as a first slave station (7), which (a) has a slave clock input (9) and (b) has a slave data bus connection (8),

(C) a third digital signal processing device which is designed as a second slave station (10) which (a) has a slave clock input (12) and (b) has a slave data bus connection (11),

(D) a data bus (19), consisting of one or more data lines, which connects the master data bus connection (3) with the slave data bus connections (8, 11), (E) a first clock line (16), which connects the first master - connects the clock output (4) to the slave clock input (9) of the first slave station (7) and (F) a second clock line (17) which connects the second master clock output (5) to the slave clock input (12) connects the second slave station (10).

2. Data transmission system (1) according to claim 1, characterized in that a plurality of further clock lines are provided, each clock line exactly one further master clock output of the same master station (2) with exactly one slave clock input each one slave station of a large number of others Connects slave stations.

3. Digital signal processing device, which is designed as a master station (2), which has at least (A) a master data bus connection (3) for connecting a data bus (19), (B) a plurality of master clock outputs (4, 5 , 6), for connecting a plurality of clock lines (16, 17, 18), (C) a selection device for selecting at least one of the master clock outputs (4, 5, 6) for outputting at least one clock signal (28, 29) and

(D) a transmitting device which transmits a data signal (27) to the data bus (19) via the master data bus connection (3) in synchronism with the clock signal (28, 29).

4. Digital signal processing device (2) after

Claim 3, namely that a receiving device is provided which receives a data signal (27) in synchronism with the clock signal (28, 29).

5. A method for transmitting a data signal (27) between a first digital signal processing device, which is designed as a master station (2), and at least one selected second digital signal processing device (7), comprising a plurality of digital signal processing devices, which act as slave Stations (7, 10, 13) are formed and are connected to the master station (2) via a data bus (19), with the following steps: (A) transmission of a clock signal (28) to the at least one selected slave Station (7),

(B) to the clock signal (28) synchronous transmission of the data signal (27) via the data bus (19), only the slave station (7) receiving the data signal (27) receiving the clock signal (28).

6. The method according to claim 5, characterized in that for the simultaneous transmission of a data signal (27) from the master station (2) to at least two slave stations (7, 10) at least two Clock signals (28, 29), in synchronism with the data signal (27), are fed to the slave stations (7, 10).

7. Method for transmitting a data signal (27) between a first digital signal processing device, which is designed as a master station (2), and at least one selected second digital signal processing device (7), comprising a plurality of digital signal processing devices, which act as slave Stations (7, 10, 13) are formed and are connected to the master station (2) via a data bus (19), with the following steps: (A) transmission of a clock signal (28) to the at least one selected slave Station (7), (B) to the clock signal (28) synchronous transmission of the data signal (27) via the data bus (19), only the slave station (7) sending the data signal (27), which the clock signal (28) receives.