COST 259 - WIRELESS FLEXIBLE PERSONALIZED COMMUNICATIONS

• Introduction
• Characteristics
• Download
• Results

Disclaimer: The scenarios and frequency assignments available from this server may be stored and processed for the development and evaluation of frequency planning methods. Any other use is not permitted.

Introduction

The COST 259 project on Wireless Flexible Personalized Communications ran from the end of 1996 to the beginning of 2000. Working groups on Radio System Aspects,Antennas and Propagation, and Network Aspects were formed and dealt with different aspect of mobile radio communications. The subgroup (SWG 3.1) of the Network Aspects working group compiled a library of GSM frequency planning scenarios. The intention was to allow comparisons of available frequency planning methods as well as to stimulated and to support the development of new methods. 32 realistic GSM network planning scenarios were collected and served already as benchmark for comparing algorithms within COST 259. The scenarios together with several contributed frequency plans are made available on this site.

All scenarios below are given in scenario format. The instance Tiny gives an example of the format. Assignments for the scenarios are given in assignment format and are accessible via the displayed links.

Characteristics

There are 32 planning scenarios available. The scenarios have been contributed from three sources, E-Plus Mobilfunk GmbH, Siemens AG, and Swisscom Ltd., in alphabetical order.

• bradford_nt-t-p
(provided by E-Plus Mobilfunk GmbH): Data for a GSM 1800 network with 649 active sites and 1886 cells. The wildcards t and p stand for five different traffic loads and three interference predictions on the basis of different signal prediction models. The basic traffic load is drawn at random according to an empirically observed distribution [Gotzner et al., 1997]. This traffic then is scaled with the factors t equal to 0, 1, 2, 4, and 10 prior to applying the Erlang-B formula in order to obtain the required number of TRXs per cell. The resulting average numbers of TRXs per cell are 1.00, 1.05, 1.17, 1.47, and 2.20, respectively. The signal predictions (p) are done assuming free space propagation with a decay factor of 1.5 (free), using a Modified Okumura-Hata model (race), and using the model developed by E-Plus (eplus), see [Eisenblätter et al., 1998] for details. The available spectrum consists of 75 contiguous frequencies. There are also variants called bradford-t-p, which are used in [Eisenblätter et al., 1998]. Due to an inaccuracy in the Monte-Carlo simulation used to derive the random traffic distribution, the TRX demand per cell in these variants is overestimated. The average numbers of TRXs per cell are 1.00, 1.57, 1.82, 2.12, and 2.60, respectively. Hence, bradford_nt-t-p is the more realistic scenario, whereas bradford-t-p provides a more complex frequency planning problem and can therefore be used as a worst-case scenario.
• siemens1
(provided by Siemens AG): Data for a GSM 900 network with 179 active sites, 506 cells, and an average of 1.84 TRXs per cell. The available spectrum consists of two blocks containing 20 and 23 frequencies, respectively.
• siemens2
(provided by Siemens AG): Data for a GSM 900 network with 86 active sites, 254 cells, and an average of 3.85 TRXs per cell. The available spectrum consists of two blocks containing 4 and 72 frequencies, respectively.
• siemens3
(provided by Siemens AG): Data for a GSM 900 network with 366 active sites, 894 cells, and an average of 1.82 TRXs per cell. The available spectrum comprises 55 contiguous frequencies.
• siemens4
(provided by Siemens AG): Data for a GSM 900 network with 276 active sites, 760 cells, and an average of 3.66 TRXs per cell. The available spectrum comprises 39 contiguous frequencies.
• Swisscom
(provided by Swisscom Ltd.): Data for a GSM 900 network in a city with many locally blocked channels and a partial assignment that has to be completed. The average number of TRXs per cell is 2.09. There are 148 cells with 1 to 4 TRXs, and 707 neighbour relations. In general, 47 frequencies are available, but 136 cells suffer from restrictions. There are only 10 available frequencies in the worst case; the median of available frequencies per cell is 19.
• K
(provided by E-Plus Mobilfunk GmbH): Data for dense urban environment in a GSM 1800 network with only 264 cells and 267 TRX in total, but the average numb er of (interference) relations per TRXs is 151. Notice: This data set is new and was not among the original COST 259 data sets.

Download

A list of the available scenarios follows. The scenarios are arranged in sections:

• bradford_nt instances
• bradford instances
• siemens instances
• Swisscom instance
• Tiny instance
• K instance

Bradford_nt-t-p Instances

Scenarios from A. Eisenblätter, Th. Kürner, R. Fauß, Radio Planning Algorithms for Interference Reduction in Cellular Networks in Communications for the Millenium, Proceedings of the COST252/259 Joint Workshop 1998, University of Bradford, pp. 87-92.

Data for a GSM 1800 network with 649 active sites and 1886 cells. The basic traffic load is drawn at random according to an empirically observed distribution. This traffic then is scaled with the factors t equal to 0, 1, 2, 4, and 10 prior to applying the Erlang-B formula in order to obtain the required number of TRXs per cell. The resulting average numbers of TRXs per cell are 1.00, 1.05, 1.17, 1.47, and 2.20, respectively. The signal predictions are done assuming free space propagation with a decay factor of 1.5 (free), using a Modified Okumura-Hata model (race), and using the model developed by E-Plus (eplus). The available spectrum consists of 75 contiguous frequencies.

bradford-0-eplus (1637488 Byte)

Propagation model: E-Plus model; Traffic factor t=0.
There are currently 5 frequency assignments available for this scenario.
BRADFORD-0-EPLUS.tgz

bradford-0-free (817691 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=0.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-0-FREE.tgz

bradford-0-race (674288 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=0.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-0-RACE.tgz

bradford_nt-1-eplus (1640529 Byte)

Propagation model: E-Plus model; Traffic factor t=1.
There are currently 5 frequency assignments available for this scenario.
BRADFORD_NT-1-EPLUS.tgz

bradford_nt-1-free (817836 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=1.
There are currently 4 frequency assignments available for this scenario.
BRADFORD_NT-1-FREE.tgz

bradford_nt-1-race (674421 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=1.
There are currently 4 frequency assignments available for this scenario.
BRADFORD_NT-1-RACE.tgz

bradford_nt-2-eplus (1640703 Byte)

Propagation model: E-Plus model; Traffic factor t=2.
There are currently 5 frequency assignments available for this scenario.
BRADFORD_NT-2-EPLUS.tgz

bradford_nt-2-free (817963 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=2.
There are currently 4 frequency assignments available for this scenario.
BRADFORD_NT-2-FREE.tgz

bradford_nt-2-race (674556 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=2.
There are currently 4 frequency assignments available for this scenario.
BRADFORD_NT-2-RACE.tgz

bradford_nt-4-eplus (1640871 Byte)

Propagation model: E-Plus model; Traffic factor t=4.
There are currently 5 frequency assignments available for this scenario.
BRADFORD_NT-4-EPLUS.tgz

bradford_nt-4-free (818188 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=4.
There are currently 4 frequency assignments available for this scenario.
BRADFORD_NT-4-FREE.tgz

bradford_nt-4-race (674792 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=4.
There are currently 4 frequency assignments available for this scenario.
BRADFORD_NT-4-RACE.tgz

bradford_nt-10-eplus (1641161 Byte)

Propagation model: E-Plus model; Traffic factor t=10.
There are currently 5 frequency assignments available for this scenario.
BRADFORD_NT-10-EPLUS.tgz

bradford_nt-10-free (818509 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=10.
There are currently 5 frequency assignments available for this scenario.
BRADFORD_NT-10-FREE.tgz

bradford_nt-10-race (675038 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=10.
There are currently 5 frequency assignments available for this scenario.
BRADFORD_NT-10-RACE.tgz

Bradford-t-p Instances

The following variants of the above scenarios overestimate the TRX demand per cell. This is due to an inaccuracy in the Monte-Carlo simulation used to derive the random traffic distribution, the TRX demand per cell in these variants is overestimated. The average num- bers of TRXs per cell are 1.00, 1.57, 1.82, 2.12, and 2.60, respectively.

bradford-1-eplus (1638060 Byte)

Propagation model: E-Plus model; Traffic factor t=1, overestimated.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-1-EPLUS.tgz

bradford-1-free (818150 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=1, overestimated.
There are currently 5 frequency assignments available for this scenario.
BRADFORD-1-FREE.tgz

bradford-1-race (674521 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=1, overestimated.
There are currently 6 frequency assignments available for this scenario.
BRADFORD-1-RACE.tgz

bradford-2-eplus (1637971 Byte)

Propagation model: E-Plus model; Traffic factor t=2, overestimated.
There are currently 5 frequency assignments available for this scenario.
BRADFORD-2-EPLUS.tgz

bradford-2-free (818087 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=2, overestimated.
There are currently 6 frequency assignments available for this scenario.
BRADFORD-2-FREE.tgz

bradford-2-race (674356 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=2, overestimated.
There are currently 5 frequency assignments available for this scenario.
BRADFORD-2-RACE.tgz

bradford-4-eplus (1638067 Byte)

Propagation model: E-Plus model; Traffic factor t=4, overestimated.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-4-EPLUS.tgz

bradford-4-free (818320 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=4, overestimated.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-4-FREE.tgz

bradford-4-race (674886 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=4, overestimated.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-4-RACE.tgz

bradford-10-eplus (1638183 Byte)

Propagation model: E-Plus model; Traffic factor t=10, overestimated.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-10-EPLUS.tgz

bradford-10-free (818344 Byte)

Propagation model: simple model (n = 1.5); Traffic factor t=10, overestimated.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-10-FREE.tgz

bradford-10-race (674571 Byte)

Propagation model: Modified Okumura-Hara model; Traffic factor t=10, overestimated.
There are currently 4 frequency assignments available for this scenario.
BRADFORD-10-RACE.tgz

Siemens Instances

siemens1 (209142 Byte)

Data for a GSM 900 network with 179 active sites, 506 cells, and an average of 1.84 TRXs per cell. The available spectrum consists of two blocks containing 20 and 23 frequencies, respectively.
There are currently 5 frequency assignments available for this scenario.
SIEMENS1.tgz

siemens2 (253437 Byte)

Data for a GSM 900 network with 86 active sites, 254 cells, and an average of 3.85 TRXs per cell. The available spectrum consists of two blocks containing 4 and 72 frequencies, respectively.
There are currently 6 frequency assignments available for this scenario.
SIEMENS2.tgz

siemens3 (555922 Byte)

Data for a GSM 900 network with 366 active sites, 894 cells, and an average of 1.82 TRXs per cell. The available spectrum comprises 55 contiguous frequencies.
There are currently 6 frequency assignments available for this scenario.
SIEMENS3.tgz

siemens4 (1127992 Byte)

Data for a GSM 900 network with 276 active sites, 760 cells, and an average of 3.66 TRXs per cell. The available spectrum comprises 39 contiguous frequencies.
There are currently 6 frequency assignments available for this scenario.
SIEMENS4.tgz

Swisscom Instance

Swisscom (7059 Byte)

Data for a GSM network in a city with many locally blocked carriers (148 cells with 1 to 4 TRXs, 707 neighbour relations, 47 carriers available in general but 136 cells are restricted to use, in the worst case, only 10 carriers and 19 carriers as a median value).
There are currently 5 frequency assignments available for this scenario.
SWISSCOM.tgz

Tiny Instance

Tiny (629 Byte)

This tiny scenario gives an example for the file formats used for scenarios and frequency assignments.
There is currently 1 frequency assignment available for this scenario.
TINY.tgz

K Instance (new)

K (193858 Byte)

Data for dense urban environment in a GSM 1800 network with only 264 cells and 267 TRX in total, but the average numb er of (interference) relations per TRXs is 151 (provided by E-Plus Mobilfunk GmbH).
There are currently 2 frequency assignments available for this scenario.
K.tgz

Results

115 assignments are currently available, with at least two assignments for every scenario. Most of the employed planning methods are described in Section 4.2.4 of [COST259, 2000]. Table 1 introduces some acronyms to simplify notation, states the algorithmic principle of the methods, and gives references to the original literature.

A number of characteristics are determined for each assignment. All of these characteristics together should allow a fair comparison of assignments for the same scenario. A sound comparison of the run-times is unfortunately not possible. In most cases the run-time is, in fact, not known. The following are rough estimates: DC5_IM(ZIB) and U(Siemens) typically compute an assignment within several minutes time, whereas all other methods from Table 2 typically have a run-time of a few to several hours on a modern PC. Notice also that results of particular implementations of heuristics are compared. Especially for the run-time intensive two local search heuristics considered here, namely, Simulated Annealing and Threshold Accepting, the produced frequency plans (and their quality) as well as the run-time (if not set explicitly) depend significantly on the implementation and on how much effort is spent in tuning the program.

The characteristics of the assignments presented for comparison are the following:

• The total interference is the sum over all co- and adjacent-channel interference occurring between pairs of cells.
• The co- and adjacent-channel interference is given in terms of the maximum, average (among the occurrences), and standard deviation of interference of each type. These figures are computed on the basis of the sum of the (two) directed interference predictions for pairs of cells.
• The interference for TRXs is given in terms of the maximum, average (among the occurrences), and standard deviation as well. The basis is here the amount of the interference a TRX causes in and suffers from other cells.
• The histogram of interference displays how many times the interference between two carriers exceeds the value of 1, 2, 3, 4, 5, 10, 15, 20, and 50% of affected cell area, respectively.

• bradford_nt instances
• bradford instances
• siemens instances
• Swisscom instance
• K instance (new)