JP3154466B2 - Usage parameter control circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to an asynchronous transfer mode (Asyn
chronous Transfer Mode (hereinafter referred to as "ATM"). In particular, usage parameter control (Usage Paramete) that monitors and controls user traffic
r Control (hereinafter referred to as “UPC”) circuit.

[0002] UPC stands for virtual channel (hereinafter referred to as "VC") and virtual path (hereinafter referred to as "VP").
After the setting is made, it is monitored whether the inflowing cell from the connection into the network does not violate the previously declared value, and the violating cell is discarded or tagged at that time. Transfer to the network and discard it according to the congestion state in the network.

[0003]

2. Description of the Related Art A leaky bucket method has been well known as a UPC technique. In the leaky bucket method, the cell flow is monitored by the depth of the “bucket with holes”. This is shown in FIG. The cells flowing into the bucket having the depth Ba are sent into the network at a constant speed corresponding to the magnitude Ra of the leak. If the inflow is too high, the bucket will overflow and the cell will be discarded.

FIG. 6 shows an example of a circuit configuration. This circuit includes a cell identification unit 1, an up / down counter 2, a subtraction timer 3, a comparison circuit 4, a threshold circuit 5, and a cell discard unit 6. The cell identification unit 1 determines whether or not the arrival cell is a valid cell.
Up. The subtraction timer 3 periodically lowers the up / down counter 2 at the rate of Ra. The comparison circuit 4 compares the value of the up / down counter 2 with the value of the threshold circuit 5, and when the value of the up / down counter 2 exceeds the value of the threshold circuit 5, issues a discard instruction to the cell discard unit 6. In addition to the output, the value of the up / down counter 2 is decremented accordingly.

[0005] In addition to main information, a plurality of types of additional information called sub-components exist in a user signal in an ATM per user. Examples of subcomponents include OAM (Operation Administration and
Mentenance) There are cells and alarm cells that are issued when a failure occurs. As an example of an OAM cell, like a MC cell (monitoring cell), a cell including the parity of the 128 main information cells is added to a 128 main information cell to form a block of 129 cells, and cell loss and bit error in the network are generated. (B-ISDN technology, published by Ohmsha, October 1993). These subcomponents are inserted asynchronously with the main information. This is shown in FIG. Main information and subcomponents are collectively called components.

[0006] If there is more than one component to a user's signal, the magnitude R _a and depth B _a bucket leakage in conventional leaky bucket scheme, T ₁ the cell spacing in the main information, the burst tolerance (cell Τ ₁ , the cell interval of each subcomponent is T ₂ ,
T ₃ ,..., T _c , the burst tolerance is τ ₂ , τ ₃ ,
.., Τ _c , _Ra = 1 / T ₁ + 1 / T ₂ +... + 1 / T _c = 1 / Ta B _a = (1 + τ ₁ / T ₁ ) + (1 + τ ₂ / T ₂ ) +.
(1 + τ _c / T _c ).

[0007]

However, in the conventional leaky bucket method, when a user signal includes a plurality of components, the traffic may be unpredictable due to malicious intention of the user. For example, when there are two components, Ta = T ₁ T ₂ / (T ₁ +) with respect to the cell intervals T ₁ and T _{2 of} these two components.
T ₂ ) <T ₁ , Despite T ₂ , two cells may pass through the bucket during 2Ta. When there are three components, there is a possibility that three cells pass during 3Ta.

In order to prevent this, it has been considered to monitor and control using a separate leaky bucket for each subcomponent. FIG. 8 simply shows a configuration example for that purpose. In this configuration, the main information and the individual sub-components are separated by the component separation unit 7, and the respective traffics are monitored by leaky buckets 8-1 to 8-c provided for each component. Violating cells are discarded by the cell discarding unit 9.

However, when a leaky bucket is provided for each component, accurate polishing can be performed.
When the number of components is increased, there is a disadvantage that a large amount of hardware is required.

[0010] It is an object of the present invention to solve the above-mentioned problems and to provide a UPC circuit capable of accurately monitoring cell traffic with a small amount of hardware.

[0011]

The UPC circuit of the present invention comprises:
Monitoring means for monitoring a transmission signal including a cell of main information and a cell of ancillary information; and, when the difference between the amount of the arriving cell and the allowable traffic amount exceeds a predetermined value, the cell is monitored. In a usage parameter control circuit including a discarding unit for discarding, a monitoring unit monitors a difference between an amount of an incoming cell and an amount of a cell corresponding to a traffic amount allowed for a cell of main information. Means, and when the difference value monitored by the first means exceeds a predetermined value, a cell corresponding to the excess cell amount and the traffic amount allowed for the cell of the incidental information. And second means for monitoring the difference from the amount.

The first means includes a first counter which counts up upon arrival of the cell and is periodically counted down in accordance with the traffic amount allowed for the cell of the main information. A second counter that counts up when the count value of the counter is larger than a predetermined first threshold value and that periodically counts down in accordance with the traffic amount allowed for the cell of the accompanying information; When the count value of the first counter exceeds the first threshold value and the count value of the second counter exceeds a predetermined second threshold value, Means for designating disposal.

[0013]

In a UPC circuit for performing connection monitoring control on a user signal including a plurality of components,
Two leaky buckets are provided, and information exceeding the first leaky bucket is monitored by the second leaky bucket. Specifically, when a cell arrives, the first counter is counted up, and when the count value is larger than the first threshold value, the second counter is counted up and the count value is set to the second count value. The threshold value is compared with the threshold value, and if both the first and second counters exceed the threshold value, it is determined to be a violation.

[0014]

FIG. 1 is a block diagram showing a UPC circuit according to an embodiment of the present invention, and FIG. 2 is a diagram conceptually explaining the UPC circuit. The UPC circuit combines two leaky buckets, and when one leaky bucket overflows, puts the information in the other leaky bucket and suspends discard diagnosis. That is, as a monitoring means for monitoring a transmission signal including a cell of main information and a cell of ancillary information, a cell identification unit 1 and an up / down counter 2
-1, a first leaky bucket comprising a subtraction timer 3-1, a comparison circuit 4-1 and a threshold circuit 5-1; an up / down counter 2-2; a subtraction timer 3-2; a comparison circuit 4-2; A second leaky bucket comprising a threshold circuit 5-2, and a cell as discarding means for discarding the cell when the difference between the amount of arriving cells and the allowable traffic amount exceeds a predetermined value. A disposal unit 6 is provided. Here, the first leaky bucket monitors the difference between the amount of cells arriving and the amount of cells corresponding to the traffic amount allowed for the cell of the main information. When the value of the difference monitored by the first leaky bucket exceeds a predetermined value, the second leaky bucket indicates the amount of cells that have exceeded the predetermined value and the amount of traffic allowed for the cells of the incidental information. The difference from the cell amount corresponding to is monitored.

Referring to FIG. 2, the first leak
The bucket is intended to monitor the main information,
Over the first leaky bucket
It is intended to monitor the amount of traffic that has been generated. This
Here, the traffic parameter of the main signal is set to (T₁,
τ₁), Traffic paras of other subcomponents
Meter (T_Two, Τ_Two), (T_Three, Τ_Three), ...
T_iIs the peak cell interval, τ_iIs a CDV tolerant (Yura
Maximum value). At this time, the first leaky bucket
The size of the leak R₁And depth B₁Is R₁= 1 / T₁ B₁= 1 + τ₁/ T₁ And Also the size of the leaky second leaky bucket
R_SAnd depth B_SIs  R_S= 1 / T_Two+ 1 / T_Three+ ... = Σ1 / T_i B_S= Σ (1 + τ_i/ T_i). Where Σ represents the sum of i = 2 to c, and c is
Number of components.

Referring again to FIG. 1, the operation of the embodiment will be described. The arriving cell is input to the cell identification unit 1. The cell identification unit 1 determines whether or not the cell is a valid cell, and if the cell is a valid cell, increments the up / down counter 2-1. The subtraction timer 3-1 periodically lowers the up / down counter 2-1 at the rate of R1. Comparison circuit 4-1
Is the value of the up / down counter 2-1 and the threshold circuit 5-
The threshold value is compared with the threshold value B1, and if the threshold value B1 is not exceeded, the cell is accepted. If the threshold value B1 has been exceeded, the up / down counter 2-2 is incremented. On the other hand, the subtraction timer 3-2 periodically lowers the up / down counter 2-2 at the rate of RS. However, the up-down counter 2-1 and 2-2 it does not become negative. The comparison circuit 5-2 includes an up-down counter 2-
Is compared with the threshold value BS of the threshold circuit 5-2. If the value exceeds the threshold value BS, it is considered to be a violation and a discard command is sent to the cell discarding unit 6, and at the same time, the up / down counter 2 -1 and 2-2 are subtracted by that amount.

According to the above operation, when traffic exceeding the traffic expected by the main information arrives, the traffic is reserved in the second leaky bucket and monitored. For this reason,
It is possible to efficiently implement monitoring and control of a connection composed of a plurality of components.

FIG. 3 shows a conventional U for user traffic.
3 shows passing traffic patterns between a PC circuit and the UPC circuit of the present invention. (A) is a traffic pattern that users might be delivered, (b) the traffic patterns that may Ri near when a conventional single bucket, a pattern by UPC circuit (c) the present invention Show. Conventional UP
In the C circuit, for example, there may be a passing pattern in which three cells are transmitted during 3Ta and repeated. On the other hand, in the UPC circuit of the present invention, the passage of such a traffic pattern is not recognized at all. FIG. 3C shows the worst pattern of the passage pattern.

FIG. 4 shows a comparison of the monitoring accuracy between the UPC circuit of the present invention and the conventional one. Here, when the number of subcomponents is 1, 2, and 4, the pattern after passing through the UPC circuit indicates how much impact the buffer of the first stage switch has. Although it depends on the number of sub-components, it can be seen that the UPC circuit of the present invention is capable of more accurate UPC than the conventional one.

[0020]

As described above, the UPC circuit of the present invention provides a UPC circuit having a plurality of components.
A PC can be accurately realized using a small circuit. Also, the amount of hardware can be greatly reduced as compared with the case where each component has a leaky bucket.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a UPC circuit according to an embodiment of the present invention.

FIG. 2 is a diagram conceptually illustrating an example circuit.

FIG. 3 is a diagram showing passing traffic patterns between a conventional UPC circuit and a UPC circuit of the present invention for user traffic.

FIG. 4 is a diagram showing a comparison of monitoring accuracy between the UPC circuit of the present invention and a conventional one.

FIG. 5 is a diagram showing the concept of a leaky bucket scheme.

FIG. 6 is a block diagram showing a conventional example of a leaky bucket type UPC circuit.

FIG. 7 is a diagram showing a relationship between main information and subcomponents.

FIG. 8 is a simplified block diagram showing a conventional UPC circuit for monitoring and controlling using a separate leaky bucket for each subcomponent.

[Explanation of symbols]

 1 Cell identification unit 2, 2-1, 2-2 Up / down counter 3, 3-1 and 3-2 Subtraction timer 4, 4-1 and 4-2 Comparison circuit 5, 5-1 and 5-2 Threshold value Circuit 6, 9 Cell discarding unit 7 Component separation unit 8-1-1 to 8-c Leaky bucket

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04L 12/28 H04L 12/56

Claims (2)

(57) [Claims] (1)The amount of cells arriving from the user and the user
The difference between the traffic volume allowed forSupervisor to monitor
Visual means,Said When the difference exceeds a predetermined value,
Usage parameter system with discarding means for discarding cells
In your circuit,The cell arriving from the user includes the cell of the main information,
Additional information inserted asynchronously into the main information cell.
Information cell,  The monitoring means,From the user The amount of cells arriving andSaidIn the main information cell
Monitor the difference between the allowed traffic volume and the cell volume.
The first means to be monitored and the difference value monitored by the first means are predetermined.
When the value exceeds the specified value,SaidIncidental
Corresponding to the traffic volume allowed for
Second means for monitoring the difference from the
Usage parameter control circuit. 2. The first means includes a first counter that counts up upon arrival of a cell and is periodically counted down in accordance with a traffic amount allowed for a cell of main information, and the second means. Is counted up when the count value of the first counter is larger than a predetermined first threshold value, and is periodically counted down in accordance with the traffic amount allowed for the cell of the incidental information. The second counter, the count value of the first counter exceeds the first threshold value, and the count value of the second counter exceeds a predetermined second threshold value. 2. The usage parameter control circuit according to claim 1, further comprising means for designating cell discarding to said discarding means.