In accordance with the present invention, a signal generator providing multiple signals with different frequencies includes, in a combined form, a clock (1), an address counter (2), a memory (3), and a digital-to-analog converter (4), which are to be series-connected. Individual storage locations within the memory (3) shall be preloaded with amplitude samples for the entire group of signals with different frequencies, which are to be selected in such a manner that storage locations in use within the aforementioned memory (3) shall contain an integral number of cycles for each signal. The address counter (2), which is controlled by the clock (1), shall successively address each storage location within the memory (3), and a capacitor (5) connected to the converter output shall be used to smooth the resulting signal. Applicable for systems permitting prompt transmission of multiple messages within railway systems, by use of contact ramps.
Description
The present invention pertains to a generator which is capable of producing multiple signals with different frequencies and, in particular, is suitable for prompt transmission of multiple messages for railway applications. Prior art includes a method of prompt message transmission for railway systems involving use of contact ramps within sets of tracks. This type of message transmission system usually consists of a unit installed aboard a train which includes, on one hand, a transmitter constantly sending multiple signals with different frequencies along two conducting wires, and on the other hand, a signal detector which is connected to the two conducting wires. In turn, one of the conducting wires is connected to a trackway by means of at least one of the train's wheels, whereas the other wire is connected to a collector shoe. At specific locations on the ground, each contact ramp is connected to the trackway by means of at least one resonant circuit in such a manner that shunting of the detector shall occur during contact between the collector shoe and the contact ramp. Accordingly, when the train travels past the contact ramp, the detector ceases to detect the signal whose frequency matches the frequency of the aforementioned resonant circuit. The absence of a signal with a specific frequency or the absence of a combination of signals with specific frequencies is then interpreted aboard the train. This situation can represent the status of the signal light which the train has most recently passed, or the distance which it must travel until the next signal light, for example. This type of system offers the advantage of being composed of entirely unenergized components at the ground level. Accordingly, maintenance is not required. In accordance with state of the art methods, thirty-two signals with different frequencies can be employed for a system of this type, and these signals are generated by thirty-two parallel-connected oscillators. An object of the present invention is simplification of the transmitter within the previously cited system, by use of a generator which shall include only one clock. In summary, with the present invention, the aforementioned generator shall include a clock, an address counter, a memory, and a digital-to-analog converter. The memory shall be preloaded according to individual storage locations, so that an amplitude sample for the entire group of signals being transmitted with different frequencies shall be stored in each one. In turn, the address counter, which is controlled by the clock, shall successively address each of the storage locations being used within the memory, where the output terminal shall provide the sample amplitude for the entire group of signals in a digital form. The digital-to-analog convertor shall then allow production of a sample analog signal which is to be equivalent to the entire group of signals being transmitted. A capacitor shall also be included, for smoothing the analog signal which is to be obtained. In order for the signal generator to function properly, frequencies for each signal must be selected in such a manner that the number of cycles stored within the memory shall be an integer. From another perspective, the present invention likewise pertains to a transmitter intended for a prompt message tranmission system for railway applications, whereby a generator shall be capable of producing multiple signals with different frequencies, characterized by the fact that only one clock and a series of parallel-connected branches shall be combined, with each branch containing a series consisting of a read-only memory, a digital-to-analog converter, and a resistor. A smoothing capacitor and an amplifier shall be connected to the output for each branch. Parallel memory-loading shall be performed according to individual storage locations, in order to allow storage of an amplitude sample for a portion of the previously cited signals with different frequencies which have been selected in such a manner that the aforementioned storage locations shall contain an integral number of cycles for each signal. In turn, each address counter, which shall be controlled by the clock, shall successively address each of the storage locations being utilized within the particular branch to which the address counter is connected.
The subsequent non-restrictive description, which is accompanied by a set of diagrams, shall permit fuller understanding of the present invention, as well as providing a clearer indication of other purposes, advantages, and characteristics of said invention. FIG. 1 is a diagram representing a signal generator designed in accordance with the present invention. FIG. 2 is a diagram representing a transmitter for a prompt transmission system for multiple messages, intended for railway applications. This particular transmitter makes use of a signal generator designed in accordance with the present invention.
Within the previously cited diagrams, a signal generator of the type to which this invention pertains essentially consists of a clock (1), and address counter (2), a read-only memory (3), and a digital-to-analog converter (4), which are to be series-connected, along with a capacitor (5) which is to be connected to the converter output (4), for the purpose of smoothing the output signal. The output signal shall consist of the sum of multiple sinusoidal signals with different frequencies. In turn, each storage location within the read-only memory (3) shall contain in a digital form a sample of the amplitude of the entire group of signals with frequencies differing from the frequency of the output signal. Reading of the memory (3) shall be performed without difficulty because of an address counter (2) which shall successively address each of the storage locations being utilized within the memory (3). The address counter shall be controlled by a clock (1), such as a quartz clock. The output signal furnished by the memory shall subsequently be converted by the digital-to-analog converter (4), so as to obtain an analog output signal which is essentially identical to the sum of the sinusoidal signals with different frequencies, for which amplitude samples shall have been preloaded within the memory (3) in a digital form. As indicated within FIG. 2, which represents a transmitter for a prompt message transmission system intended for railway applications, the entire system is controlled by a clock (1). In this instance, the transmitter consists of two branches, and each branch includes a series consisting of an address counter (21, 22), a read-only memory (31, 32), and a digital-to-analog converter (41, 42). The resistors identified as (51) and (52) and the capacitor identified as (53) are respectively intended to allow integration of signals emanating from each branch and smoothing of these signals. The signal which is obtained is transmitted to an input terminal within an amplifier (6) whose output terminal (7) shall, for example, be connected to an isolating transformer which does not appear within the diagram. The terminals on the secondary winding within this transformer shall function as the output terminal of the previously cited transmitter. According to one embodiment of the present invention, the transmitter is designed so as to transmit thirty-two signals with different frequencies, which shall differ from one another by approximately 10 percent. In addition, there shall be a quartz clock operating a 12 MHz. In order to obtain a continuous signal, it is necessary for the sample stored within the first storage location of the memory to fit together with the sample stored within the last storage location. In other words, an integral number of cycles must be stored for each signal. If the minimum frequency of the signals which are to be transmitted is equivalent to approximately 3000 Hz, it is sufficient to install a 16- divider, which does not appear within the diagram, at the clock output and to store the signal amplitudes in 250 storage locations within the memory (31) during nine alternations. Hence, it is possible to use 2250 storage locations. It is easy to provide this configuration inasmuch as 4,000-octet memories and suitable dividers are commercially available. The address counter must therefore be preset so that it shall only scan a portion of the memory field. In order for amplitudes stored at various locations within the memory (31) to match one another, it is necessary to select signals which likewise permit storage of an integral number of cycles within the same number of storage locations. When a minimum frequency of 3,000 Hz is selected, it is possible to store nine cycles within the memory. The frequencies of other signals permit storage of ten, eleven, and twelve cycles, for example. Then it is possible to select the following frequencies: 3333.33 Hz, 3666.67 Hz, and 4000 Hz, with an average separation of approximately 10 percent. In order to maintain a similar average separation among the different frequencies, it then becomes necessary to make use of a higher octave (6000 Hz, 6666.67 Hz, and 8000 Hz, respectively). For this particular embodiment of the present invention, the sample amplitudes for sixteen signals with different frequencies have been stored at storage locations within both of the memories identified as (31) and (32). By applying the same concepts, 3024 storage locations are used within the memory identified as (32), and minimum frequencies of 4464.23 Hz, 4960.32 Hz, and 5456.35 Hz have been selected, in order to permit storage of nine, ten, and eleven signal cycles within the memory. It is possible to use only one memory within this type of transmitter, although, in this particular instance, the output signal is not clearly defined and the signal-to-noise ratio is unsuitable, on account of the fact that the output signal shall be generated in a staggered form. Hence, it is preferable to limit the number of signals with different frequencies which are to be stored in each memory and to provide several identical parallel-connected branches, whose outputs shall be connected to an analog integration circuit. Although the preceding description pertains solely to the preferred embodiment of the present invention, it is obvious that any modifications introduced for the same purposes by technically knowledgeable persons would not represent departures from the context of this invention. In particular, the number of sections for the transmitter described heretofore is not restricted to two sections.
Claims
1. Signal generator apparatus comprising a memory having storage locations storing, in digital form, successive samples of the amplitude of the sum of a multiple number of analog signals of different predetermined frequencies, said frequencies being selected such that said samples collectively correspond to a different integer number of cycles for each of said signals, address counter means connected to said memory for successively addressing said storage locations, a clock connected to control said address counter means, digital-to-analog converter means connected to said memory for converting said samples into an analog signal which is substantially equivalent to said sum of said signals, and capacitative smoothing means connected to the output of said digital-to-analog converter means for smoothing the analog signal output of said digital-to-analog converter means.
2. Signal generator apparatus in accordance with claim 1, wherein said memory is a read only memory.
3. In a railway communication system of the type in which a train carries an on-board transmitter connected for transmitting multiple analog signals of different frequencies into a trackway and an on-board detector connected to detect the signals transmitted into the trackway, and in which contact ramps are disposed along the trackway and connected thereto by respective resonant circuits for shunting the on-board detector at one or more of the predetermined frequencies in order to convey a message to the train,
the improvement wherein said transmitter has a signal generator comprising:
a plurality of parallel-connected branches each having a memory with storage locations storing, in digital form, successive samples of the amplitude of the sum of a respective group of said signals, the frequencies of the signals of said group being selected such that said samples collectively correspond to a different integer number of cycles for each signal of said group, address counter means connected to said memory for successively addressing said storage locations, and digital-to-analog converter means connected to said memory for converting said samples into an analog signal substantially equivalent to said sum of the signals of said group,
a clock connected to control the address counter means of said branches,
the outputs of the respective digital-to-analog converter means of said branches being connected together and jointly providing an analog signal output which is substantially equivalent to the sum of said multiple analog signals, and
capacitive smoothing means connected to the outputs of the respective digital-to analog converter means for smoothing the output signals of the respective digital-to analog converter means.
4. The improvement of claim 3, wherein said capacitive smoothing means comprises a smoothing capacitor, and wherein each branch includes a resistance connecting the output of the digital-to-analog converter means of that branch to a terminal of said smoothing capacitor and to the input of an amplifier.
5. The improvement of claim 4, wherein said branches are two in number.
6. The improvement of claim 5, wherein each of said groups of signals is composed of 16 signals of different frequencies.
Priority Claims (1)
Number
Date
Country
Kind
84 14784
Sep 1984
FRX
Non-Patent Literature Citations (1)
Entry
Kinsel, T. S. et al., A Digital Signal Generator, from IEEE Micro., Nov. 1981, pp. 6-15.