FR2660501A1 - Network simulator in asynchronous time-based technology - Google Patents

Abstract

The network simulator in asynchronous time-based technology is connected to sending-end equipment and to receiving-end equipment. It comprises cell reception means (M1), means (M2) for recording the time of reception of each cell, means (5, 6, 7, 8, 9) for delivering a transmission time, means for injecting foreign cells (11, 12) and means for introducing a bit-error configuration (13) on a byte of one cell.

Description

Network simulator in asynchronous time technology
The invention relates to networks in asynchronous time technique in which the information is transmitted by cells of fixed length.

 The object of the invention is to make it possible to measure the performance of the celluler / decellulator organs which are the end devices for converting information into cells, and conversely from cells into information delivered, in series or in parallel, to a receiver.

 The invention relates to a network simulator in asynchronous time technique, connected on the one hand to a transmission end equipment and on the other hand to a reception end equipment, characterized in that it comprises means for receiving cells emitted by the transmitting end equipment, means for suppressing active cells, means for introducing jitter on the transfer time, means for injecting foreign cells to inject a foreign cell in replacement of an empty cell, connected to the reception means, and means for introducing a bit error configuration on a byte of an active cell, connected to the foreign cell injection means and to the reception end equipment.

 The invention will be described using an exemplary embodiment illustrated by the appended figures in which - FIG. 1 represents a reference configuration illustrating the connection of a simulator of the invention with end devices, - Figure 2 is a general diagram of the simulator of the invention.

 In FIG. 1, a network simulator 1 is connected by a reception interface Iu to a transmission end equipment 2, and by a transmission interface Id to a reception end equipment 3.

 The simulator 1 receives by the reception interface Iu a byte clock signal SHOR, a cell clock signal SHCR, data on a reception link DOR with eight wires in parallel, an active cell presence signal SCAR.

 The simulator 1 transmits by the transmission interface Id a byte clock signal SHOE, a cell clock signal SHCE, data on a transmission link DOE with eight / wires in parallel.

 On the other hand the simulator 1 is connected by a command interface Ic to a push button for each function introduced via the simulator for the isolated actions, to a periodic signal input for each function introduced by the simulator for the actions at higher frequencies.

 FIG. 2 represents, by way of example, the general diagram of the network simulator of the invention. A memory M, of FIFO type, consists of a cell memory M1 and a reception time memory M2. The cell memory receives the cells via the DOR reception link, and the reception time memory M2 is connected as an input to a counter 4, of eight bits, which receives the cell clock signal SHCR and delivers a reception time signal Tr relative to a received cell. The memory M also receives the signal SHCR, the active cell presence signal SCAR and the byte clock signal SHOR. The memories M1 and M2 respectively constitute a means of receiving cells and a means of recording the time of reception of each cell.

A programmable read only memory 5 is connected at the input, on the one hand to a jitter circuit 6 having for example five micro-switches, and on the other hand to a counter 7, of three bits, controlled by an external signal F ext. The read-only memory 5, of 256 words of 8 bits is connected at the output to an input of an adder 8 to which it delivers a jitter time Tj, variable. Another input of the adder 8 is connected to the output of the reception time memory
M2 from which it receives the reception time Tr. At the output the adder 8 is connected to an input of a comparator 9 to which it delivers an emission time signal Te which is equal to Tr + Tj. The comparator 9 has another input connected to a local time base 10 which delivers a local time signal HL; when the emission time Te is equal to or greater than the local time HL, the comparator delivers on its output a read command signal to the cell memory
M1.

 The programmable read-only memory 5, the jitter circuit 6 and the counter 7 constitute a variable time generator. This generator, the adder 8 and the comparator 9 constitute means for delivering to the cell reception means (memory M2), and for each cell, an emission time obtained by adding a variable time to the reception time.

 A multiplexer 11 has an input connected at the output of the cell memory M1 and another input connected at the output of a circuit for choosing a virtual circuit number 12, said circuit comprising for example microswitches for choosing this number. At output the multiplexer 11 is connected to an input of another multiplexer 13 having another input connected to a bit error circuit 14 delivering an error pattern on eight bits; the bit error circuit 14 is for example constituted by eight microswitches.

 The multiplexer 13 is connected at output to the transmission interface Id to which it delivers a byte clock signal, a cell clock signal and cell bytes.

 The multiplexer 11 and the circuit 12 constitute means for injecting foreign cells, the multiplexer 13 and the bit error circuit 14 constituting means for introducing a bit error configuration on a byte of an active cell.

 The network simulator of the invention is used to loop back the transmission end equipment 2 to the reception end equipment 3, by transmitting the signals from the reception interface Iu to the transmission interface Id. The presence signal active cell SCAR is converted into an empty cell identified on the transmission interface Id by a particular virtual circuit number, in accordance with the principles of the asynchronous time technique. The content of the information field of an empty cell consists of a succession of "11110000" patterns according to the CCITT recommendations.

 The simulator allows the introduction of bit error, which consists in replacing a byte of a cell by a byte delivered by the bit error circuit. The frequency of this bit error injection is between the isolated injection, that is to say the single shot, and 1 MHz.

For this, the multiplexer 13 has a control input 13a which receives a signal either from a push button, or at each period of an external signal.

 The simulator makes it possible to simulate an active cell loss, by replacing an active cell with an empty cell as defined above. The cell is lost at the cell memory M1, and the frequency of this loss is between the single shot and 1 MHz.

 The cell loss is triggered by controlling the cell memory M1, using a PC cell loss signal, either from a push button or at each period of an external signal. The virtual circuit number on which a cell loss is caused is either any of the active virtual circuits, or a particular virtual circuit among the active virtual circuits.

 The simulator also allows the injection of foreign cells; this injection is obtained by replacing an empty cell with a cell having an active virtual circuit number.

This injection is provided by the multiplexer 11, the active virtual circuit number being delivered by the virtual circuit number choice circuit 12. The frequency of this injection of foreign cells is between the single shot and 1 MHz. The multiplexer 11 has a control input Ila which receives an injection control signal either from a push button, or at each period of an external signal.

The simulator also serves to vary the transfer time between the reception and the emission of a cell; this variation, called jitter on the transfer time, is obtained by adding a jitter time Tj to the reception time Tr to give the emission time Te = Tr + Tj. It is therefore possible, by varying Tj to vary the emission time Te. This transmission time is compared with the local time HL in the comparator 9 which delivers a read signal from the cell memory M1 when
Te is equal to or greater than local time.

 The variable jitter time Tj is stored in the programmable read-only memory 5 which contains 256 jitter configuration. The waveform of the jitter and its amplitude are chosen on the basis of a combination, wave and amplitude, from 32 using the jitter circuit 6. A waveform is defined over a period using of eight points at a frequency defined from counter 7 and equal to 1/8 of the external frequency F ext which controls this counter.

 The network simulator of the invention therefore allows the introduction of disturbances in order to test the end devices used in a network in asynchronous time technique. These disturbances are - the bit error rate; it can vary from the isolated error to the complete inversion of all the information bits, with a programmable error model (configuration of the erroneous bits within a byte), - the cell loss rate ; it can vary from the isolated loss to the suppression of all the information cells, - the rate of foreign cells; it can vary from the isolated injection of a cell to the saturation of the physical support used, - the jitter over the transfer time; the jitter introduced varies from zero to a peak-to-peak amplitude of 256 byte times, in the embodiment illustrated in FIG. 2; the jitter waveform is programmable. These disturbances greatly exceed the disturbance level of a network and make it possible to find the performance limits of the end equipment.

Claims (5)

1 / Network simulator in asynchronous time technique, connected on the one hand to a transmission end equipment (2) and on the other hand to a reception end equipment (3), characterized in that it comprises means for receiving cells emitted by the sending end equipment (2), means for suppressing active cells, means for introducing jitter on the transfer time, means for injecting foreign cells for injecting a cell foreign cell in replacement of an empty cell, connected to the reception means, and means for introducing a bit error configuration on a byte of an active cell, connected to the foreign cell injection means and to the equipment for reception end (3). 2 / network simulator according to claim 1, characterized in that the cell reception means comprise a cell memory M1, of FIFO type, connected to the transmission end equipment (2), that the means of injection of foreign cells is constituted by a first multiplexer (11) and a virtual circuit number choice circuit (12), said first multiplexer (11) having a first input connected to the cell memory (M1), a second input connected to said selection circuit (12) and a control input (lla) connected to a foreign cell injection control means, and that the means for introducing a bit error configuration are constituted by a second multiplexer (13) and a bit error circuit (14), said second multiplexer (13) having a first input connected to the first multiplexer (11), a second input connected to the bit error circuit (14) and a control input (13a) bound e to a bit error injection control means. 3 / network simulator according to claim 1, characterized in that it also comprises a means of recording, for each cell received, the time of reception, and means for delivering to the cell reception means, and for each cell received, a transmission time obtained by adding a variable time to the reception time. 4 / network simulator according to claim 3, characterized in that the means for delivering an emission time are constituted by a variable time generator (5, 6, 7), an adder (8) having a first input connected to the variable time generator, a second input connected to the means for recording the time of reception and an output connected to a first input of a comparator (9) having a second input connected to a local time base (10) and an output connected to a read control input of the cell reception means. 5 / network simulator according to claim 1, characterized in that the cell reception means are connected to a control means which delivers a cell loss signal (PC) to replace an active cell with an empty cell.