DE9112418U1 - Device for transferring data represented in a balanced code to a telegram memory module - Google Patents

Description

^GR 9 1 G 4 O 9 6

Siemens AG

Device for transferring data represented in a balanced code to a telegram memory module

The invention relates to a device according to the preamble of claim 1. Such a device is known from DE 30 46 201 C2. There, a device is reported for point-by-point information transmission from the track to railway vehicles, with the help of which information such as signal states, target and limit speeds, slip paths, track gradients, etc. can be transmitted in the form of telegrams to stationary transmission devices to passing vehicles. For this purpose, so-called track coupling coils are generally arranged on the track near signals or, for example, in front of slow-speed sections, which receive energy inductively from the train coupling coils of passing vehicles and then also inductively send a serial data stream to the train coupling coil. The information in this serial data stream is taken from two telegram memory modules; the selection of the information to be transmitted in each case is made by a selection control according to, for example, a signal aspect connected to a light signal.

Each telegram memory module contains a telegram memory module; the corresponding telegrams in the two telegram memory modules differ only by a single bit, so that the vehicle can recognize that telegram data has been received from both the one and the other telegram memory module, i.e. has been transmitted via two channels. In each telegram memory module, for example, up to 64 different telegrams, each with a maximum length of 512 telegram steps, can be stored.

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Gi/Ro / 30.09.1991

2 GR 9 1 G 4 O 9 6 The telegram memory modules are housed in the connection compartment of the associated track coupling coil together with a transmitter control module, which supplies the memory modules with readout clocks and releases them alternately for the duration of a telegram. The serial telegram data emitted by the memory modules are converted by the transmitter control module into a frequency-modulated data stream, amplified in a transmitter module and fed into the transmitting antenna of the track coupling coil.

Each telegram storage module has a certain number of so-called telegram select inputs for selecting the telegram to be transmitted, which are controlled by the selection control with a balanced code, for example a 2 out of 5 or a 2 out of 6 code. When using a 2 out of 6 code, up to 15 different pieces of information can be transmitted. The selection control is represented, for example, when transmitting telegrams determined by light signal aspects, by a signal module at the base of the respective signal mast, which converts the respective signal aspect into the balanced code used to control the telegram storage modules.

The central component of every telegram memory module is a sequence controller and an EPROM as a telegram memory. The sequence controller receives a clock and an enable signal from a transmitter module as its most important input signals: with the start of an active enable signal, the sequence controller ensures that the telegram select signals currently present, for example from a signal module, are buffered in two registers connected in parallel on the input side. The output signals of these buffers control a telegram memory module via, for example, six address inputs each and thus select an address block under which the telegram to be output is stored in the telegram memory.

During telegram output, the sequence control generates the

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3 GR 9 1 G 4 O 9 required EPROM control signals and increments the EPROM address after each output of a telegram step. The telegram selection signals transferred to the register remain unchanged for the duration of the following telegram output. Since the output signals of a signal module change completely asynchronously to the enable signal of the transmitter control module of a track device, transition states between two outputs of the signal module can also be temporarily stored in the two registers. This means that there is the possibility that in a transition phase a mixture of still unchanged and already changed bits is stored, which may represent a valid but unwanted balanced code and can therefore lead to the selection of unwanted incorrect telegrams from the telegram memories.

The object of the invention is to design the device according to the preamble of claim 1 in such a way that such undesirable mixtures between old and new control instructions are avoided.

The invention solves this problem in the aforementioned device by applying the characterizing features of claim 1. Advantageous embodiments of the device according to the invention are specified in the subclaims.

The invention is explained in more detail below using an embodiment shown in the drawing. The drawing shows

Figure 1 shows a schematic of a device for transmitting information from the track to a passing vehicle,

Figure 2 shows a block diagram explaining the selection procedure and the output of a telegram to the transmitter of a track coupling coil and Figures 3 and 4 show two representations of successive

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Official file no. G 91 12 418.2 4 GR 91 G 4096 DE

at the select inputs of a buffer

applied select signals.

Figure 1 shows a schematic of a light signal LS with a signal assembly SBG housed in a switch box on the signal mast or in its vicinity, which can be controlled via control lines L from a signal box (not shown) to connect different signal aspects. At this signal assembly, an identifier is taken from the respective signal aspect that is connected and fed to an adjacent track coupling coil GKS. This track coupling coil is used in a known manner to transmit information in the form of time-multiplexed or frequency-multiplexed coded telegrams to vehicles passing on a track F and, if necessary, to receive telegrams transmitted from there and to pass them on to an evaluation point, e.g. the signal box, in a manner not shown. The track coupling coil GKS takes the energy required for transmitting telegrams to passing vehicles from the vehicle-side coupling coil of passing vehicles or it receives this energy from the signal assembly of the light signal or from another local or remote voltage source. The switching devices required for the operation of the track coupling coil are housed in a connection compartment A which is connected to the track coupling coil. Their interaction is shown in the diagram in Figure 2.

There, two buffers ZSpI, ZSp2 connected in parallel on the input side are shown, which can be set according to the telegram to be transmitted from the signal module of the associated light signal via telegram selection lines Si 0 to Si 5. The data to be accepted is offered to the buffers in the form of a balanced code, in this case in the form of a 2 out of 6 code.

The transferred data indicates the address of an address block within the area following the two buffers.

5 GR 9 1 G 4 O 9 6 switched telegram memory module in which the telegram currently to be output is stored. The data present via the telegram select inputs is transferred to the respective buffer under the control of clock and enable signals which are fed to the respective buffer by a transmission control SSt. The two telegram memories TSp 1 and TSp 2 of the respective associated telegram memory module are connected downstream of the buffers. The output signals of the buffers control six address inputs in the EPROMs of the two telegram memory modules. The transmitter S is activated via the transmission control SSt to alternately output the telegram taken from one and the other telegram memory. The telegram is transmitted via the antenna of the associated track coupling coil.

The current state of the telegram select signals is buffered in the buffers every time a release signal begins and is kept unchanged for the duration of the following telegram output. Since the output signals of the signal module change independently of the release signal of the transmitter control module, transition states between two outputs of the signal module can also be stored in the buffers with each telegram change. This leads to the retrieval of telegrams from the telegram memory modules that do not correspond to the actual conditions at the light signal, at least when the intermediate state corresponds to a valid select code. This relationship is explained in more detail in Figure 3. The diagram shown there shows the signal state on the telegram select lines Si 0 to Si 5 (Figure 2) leading to a buffer at successive times. During a first time period Tl, the first four telegram select lines are at high level, while lines five and six are at low level. As a result of a telegram change required by the change of a signal aspect,

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^{6 GR} 9 1 6 4 O 9 6 now the second and third telegram select lines are set to low level and the other telegram select lines to high level. The new code is transferred to the buffer in the time period Tl/2. Due to different time constants on the outputs of the selection control and the inputs of the buffer in question, first the sixth telegram select line is set to high level, then the third select line is set to low level. Then the second select line changes to low level and the fifth select line to &EEgr; level. In this phase the buffer is offered code combinations which temporarily do not meet the conditions of the agreed balanced code, but satisfy the conditions of a 1 or a 3 of 6 code. These control constellations can be made ineffective by a code check. However, it is also offered a valid 2 of 6 code in the meantime. Depending on when the release signal is fed to the buffer, this data, which is formed from two different select control signal combinations and satisfies the agreed code conditions, can be stored in the buffer and thus faulty dough rams can be output.

The device according to the invention avoids this by temporarily issuing an intermediate code with each telegram change, which modifies the previously issued date in such a way that it becomes a date that does not satisfy the agreed conditions of the equilibrium code, whereby care is taken to ensure that possible intermediate states between this new date and the original date also do not satisfy the agreed code conditions. This is achieved by, for example, the selection control issuing an intermediate code for a predetermined period of time, which has at least one additional active bit in addition to the previously active bits or in which at least one of the active bits has changed its value. This intermediate code is designed to be particularly

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Official file no. G 91 12 418.2 7 GR 91 G 4096 DE

simple if it is formed by an η of η-code or a 0 of η-code; η denotes the number of bits of the equilibrium code.

In Fig. 4, a date that is available for transfer to the buffer in a period T1 is initially shown by the designation of the value of its elements. This date is to be replaced in an intermediate section before a new date is provided by an intermediate code that does not meet the conditions of the equilibrium code, but is, for example, a 0 of η code. This 0 of n code modifies the date that was previously available in the buffer, whereby in the worst case scenario a 1 of 6 code can be offered in a period T 1/2. A date presented in this way is recognized as incorrect by the code check and rejected. The date presented in the 0 of 6 code is then present at the inputs of the buffer; this date is also not accepted by the code check. The same applies when changing from the intermediate code to the new date. Here too, in a transition phase, only one date can be created that is identified as incorrect by the code check and can be eliminated.

The intermediate code must be present for as long as the selection control needs to provide a new data item at its outputs and in particular for as long as the buffers need to prepare for the acceptance of a data item. If there are other times that affect the acceptance of a data item, such as data transfer times, their duration must also be absorbed by the duration of the intermediate code.

Instead of a 0 from &eegr; code, the intermediate code can also be designed as &eegr; from &eegr; code. In this case too, by mixing any data with the intermediate code, no data can be formed that cannot be recognized as false and that could be used to retrieve a false telegram from the telegram memories.

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8 GR 9 1 G 4 O 9 6 could lead to.

In addition to these two intermediate codes, there are any number of other intermediate codes, each of which can be formed by modifying the date that is effective before a dough frame change. Such an intermediate code can, for example, contain an additional third active bit in addition to the two active bits of an equal-weight code, or it can be formed by changing the value of at least one of the active bits. It is also possible to mix the old and new dates, whereby, for example, a 2 out of 6 code temporarily becomes an A out of 6 code. Even in the transition phases between the old code, intermediate code and new code, there is no date that satisfies the agreed conditions of the equal-weight 2 out of 6 code. The active bits of the equal-weight code can be either low-active or high-active.

The device according to the invention is not limited to use with light signals for controlling track coupling coils, but can be used advantageously wherever track coupling coils are required to transmit different information to passing vehicles. It is also not limited to use in train control systems; wherever mixing old and new control instructions can temporarily produce control information that is incorrect but not necessarily recognizable as incorrect, the invention creates a possibility for masking these incorrect control instructions.

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Claims (5)

9 GR 916 4 0 9 Protection claims 1. Device for transferring data represented in a balanced code (m of n) to a telegram memory module (TSpI, TSp2) for the provision of telegrams with different content with the help of a selection control that selects the data to be transferred and is not synchronized with the transfer of the telegrams into the telegram memory module, characterized in that with each telegram change, before the respective new telegram is specified, an intermediate code is generated for a predetermined minimum period of time, which has at least one further active bit in addition to the previously active (m) bits or in which at least one of the active bits has changed its value. 2. Device according to claim 1,
characterized in that the intermediate code is an η of η code, where η is the number of bits of the equilibrium code. 3. Device according to claim 1,
characterized in that the intermediate code is a 0 of η-code, where η is the number of bits of the equilibrium code. 4. Device according to one of claims 1 to 3, characterized in that each telegram memory module (TSpI, TSp2) contains a buffer (ZSpI, ZSp2) for receiving at least one address provided by the selection control (SBG) for the selection of an address block under which a telegram that can be called up from the telegram memory module is stored in the latter. 02 01 ^{10 GR} 916 4 0 9 5. Device according to one of claims 1 to 4, characterized in that the predetermined minimum time period is at least equal to the time period that the selection control (SBG) requires to provide a new data item at its outputs and that is required for data transmission and for preparing the telegram memory module for the acceptance of this data item. 02