### Table 1. Packet description for the Kohonen Self-Organizing Map implementation.

2002

"... In PAGE 3: ... After having read the sensor values, each unit compares those values with its internal values, stored in the randomly initialised prototype vectors and calculates the Euclidean distance between both vectors. A packet is then created and broadcast across the network with the elements as they are listed in Table1 . The timestamp is provided to eliminate outdated packages.... ..."

Cited by 9

### Table 1: Mean square error for neuron weights and stan- dard deviation for probability density estimates ( ) 6 Conclusions A new integrally distributed self-organizing learning al- gorithm for the class of neural networks introduced by Kohonen [1] was presented. The algorithm converges to an equiproblable topology preserving map for arbitrarily distributed input signals. It is shown that Kohonen apos;s al- gorthim converges to a locally a ne self-organizing map. Similations results agree with theoretical predictions.

"... In PAGE 5: ... As expected, the results of the three algo- rithms are fairly similar, for the case of a uniformly dis- tributed input signal. Table1 contains the mean square error for the neuron weights and the standard deviation of the probability density estimate vector, ^ p, for both simu- lations.It should be noted that the improvement in perfor- mance comes at an increase in computational cost.... ..."

### TABLE III COMPARISON OF THE MOTIF SETS FROM SELF-ORGANIZING NEURAL NETWORK METHOD AND MEME METHOD, NOS = NUMBER OF SAMPLES IN THE MOTIF SET.

Cited by 1

### TABLE I THE EFFECT OF NETWORK SIZE FOR THE SELF-ORGANIZING MAP (SOM) The SOM size versus detection results for three different sizes

### Table 1. Mechanisms of Self-organization in Modern Distributed Computing Scenarios

### Table 7: Kohonen self-organizing feature map of the iris data.

in Input Data Coding in Multivariate Data Analysis: Techniques and Practice in Correspondence Analysis

"... In PAGE 11: ..., 1997). Table7 shows a Kohonen map of the original Fisher iris data. The user can trace a curve separating observation sequence numbers less than or equal to 50 (class 1), from 51 to 100 (class 2), and above 101 (class 3).... In PAGE 11: ... The zero values indicate map nodes or units with no assigned observations. The map of Table7 , as for Table 8, has 20 20 units. The number of epochs used in training was in both cases 133.... In PAGE 11: ...ersion of the Fisher data. The user in this case can demarcate class 1 observations. Classes 2 and 3 are more confused, even if large contiguous \islands quot; can be found for both of these classes. The result shown in Table 8 is degraded compared to Table7 . It is not badly degraded though insofar as sub-classes of classes 2 and 3 are found in adjacent and contiguous areas.... ..."