The article presents the results of researches aimed at the creation of automated workplaces for railway transport specialists with the help of intelligent information systems. The analysis of tendencies of information technologies development in the transport network was conducted. It was determined that the most effective approach is to create an information transport architecture, together with the quality management system of transport services. Automated workplace for specialists of rail transport with this approach is synergistically formed as a local information space and process automation as part of a single intelligent information transport space in accordance with the strategy of transport development, management and information technologies. This approach allows standardizing technological processes of traffic, identifying points of risk of occurrence of security threats and information loss, forming a dynamic information environment decision support. The main problems of the effective operation of intelligent transport systems in general and each automated sites are information security, reliability of information, the stability of data transmission systems, and qualification of the personnel. The basis for the formation of local computer workstations are optional models of technological processes, taking into account the large number of situations on the railway transport options. The paper presents an example of modeling operations and assessment of the costs of the working time of commodity cashier. An analysis found fotochronometry the most appropriate for the study, which serves as the basis for action photography worker per shift with simultaneous maintenance of chronometry observations lasting one or another of his actions. The mathematical apparatus of research, calculation and optimization of logical systems is a simulation pertaining to the theory of probability, mathematical statistics and represented in terms of queuing theory. The proposed changes to modernize the automated place for commercial cashier can be embedded in the enterprises of the railway of Kazakhstan.

Agarana, M., Anake, T. & Okagbue, H. (2016). Optimization of Urban Rail Transportation in Emerging Countries Using Operational Research Techniques. Applied Mathematics, 7, 1116-1123. http://dx.doi.org/10.4236/am.2016.710099

Balog, M. et al. (2015). Automation Monitoring of Railway Transit by Using Rfid Technology. Acta Tecnología - International Scientific Journal about Technologies, 1(1), 9-12.

Banister, D. & Stead, D. (2004). Impact of information and communications technology on transport. Transport Reviews, 24(5), 611-632.

Berikbayev, N. & Isina, B. (2005). Improving the operation of a freight office. Magistral, 2005(6), 78-80.

Connolly, B. (2014). Australian rail firm in SAP first Aurizon begins deploying freight system based on SAP supply chain platform. http://www.cio.com.au/article/535718/australian_rail_firm_sap_first/

Gnatov, A. & Argun, Sch. (2015). New Method of Car Body Panel External Straightening: Tools of Method. International Journal of Vehicular Technology, 2015, 1-7. doi:10.1155/2015/192958

Gorman, F. (2015). Handbook of Operations Research Applications at Railroads, International Series in Operations Research & Management Science Springer Vol. 222. Operations Research in Rail Pricing and Revenue Management. New York: Springer Science + Business Media.

Hitachi Data Systems (2012). Hitachi Converged Solution Brings Virtualization and Top Performance to Russian Railways. Santa Clara: HDS. https://www.hds.com/assets/pdf/hitachi-success-story-russian-railways.pdf

Huang, Y. et al. (2015). Optimization of Train Operation in Multiple Interstations with Multi-Population Genetic Algorithm. Energies, 8, 14311-14329.

Inkinen, T., Tapaninen, U. & Pulli, H. (2009). Electronic information transfer in a transport chain. Industrial Management & Data Systems, 109(6), 809 – 824.

Khusainova, R., Shilova, Z., & Curteva, O. (2016). Selection of Appropriate Statistical Methods for Research Results Processing. Mathematics Education, 11(1), 303-315. 

Kim, N. & Van Wee, B. (2011). The relative importance of factors that influence the break-even distance of intermodal freight transport systems. Journal of transport geography, 19(4), 859-875.

Kour, R. et al. (2014). Applications of radio frequency identification (RFID) technology with eMaintenance cloud for railway system. International Journal of Systems Assurance Engineering and Management, 5(1), 99–106.

Kour, R., Tretten, P. & Karim, R. (2014). eMaintenance solution through online data analysis for railway maintenance decision-making. Journal of Quality in Maintenance Engineering, 20(3), 262 – 275.

Kovalenko, Ye. (2012). The methodology of designing organization information systems – the double-mirror concept. Russian Academic Journal, 2012(4), 38-41.

Lehtinen, J. & Bask Anu, H. (2012). Analysis of business models for potential 3Mode transport corridor. Journal of Transport Geography, 22, P. 96-108.

Liden, T. (2015). Railway infrastructure maintenance - a survey of planning problems and conducted research. Transportation Research Procedia, 10, 574–583.

Lietuvos Geležinkeliai (2014). Information Technology Lietuvos Geležinkeliai Annual Report. Vilnus: AB Lietuvos Geležinkeliai. http://www.litrail.lt/documents/10291/1488090/LG_2014_GB.pdf/e4462df0-04d3-4c17-86ba-2c14187fc923

Overby, S. (2016). How IT is Helping the Railroad Industry Improve Efficiency and Service http://www.cio.com/article/2433741/it-organization/how-it-is-helping-the-railroad-industry-improve-efficiency-and-service.html

Pekin, E. et al. (2013). Location Analysis Model for Belgian Intermodal Terminals: Importance of the value of time in the intermodal transport chain. Computers in Industry, 64(2), 113-120.

Rabah, M. & Mahmassani, H. (2002). Impact of information and communication technologies on logistics and freight transportation – Example of vendor-managed inventories. Freight Transportation, 2002, 10-19.

Rosová, A., Balog, M. & Šimeková, Ž. (2013). The use of the RFID in rail freight transport in the world as one of the new technologies of identification and communication. Acta Montanistica Slovaca, 18(1), 26-32.

Saatçioğlu, Ö., Deveci, D. & Cerit, A. (2009). Logistics and transportation information systems in Turkey: e-government perspectives. Transforming Government: People, Process and Policy, 3(2), 144 – 162.

SAP AG (2014). SAP Transportation Management 9.1 Overview of New Innovations for Release 9.1. Burlington: SAP. http://a248.g.akamai.net/n/248/420835/f6beca0d9c07050282302395b97883900f8723a96aec95b37b8ff2a628bf3e6d/sapasset.download.akamai.com/420835/sapcom/docs/2015/08/c0f80686-5b7c-0010-82c7-eda71af511fa.pdf

Sarraj, R. et al. (2014). Analogies between Internet network and logistics service networks: challenges involved in the interconnection. Journal of Intelligent Manufacturing, 25(6), 1207-1219.   

Skalozub, V. et al. (2013). Intelligent transport systems of rail transport (information technology fundamentals). Dnipropetrovsk: V. Lazaryan Dnipropetrovsk National University of Railway Transport Publishing House.

Smith, R. & Zhou, J. (2014). Background of recent developments of passenger railways in China, the UK and other European countries. Journal of Zhejiang University Science A, 15(12), 925–935. doi: 10.1631/ jzus.a1400295

Sun, Y., Lang, M. & Wang, D. (2014). Optimization and integration method for railway freight stations based on a hybrid neural network model. Computer Modelling & New Technologies, 18(11), 1233-1241

Timofeev, A. (2015). The Rail Traffic Management with Usage of COTDR Monitoring Systems. In Proceedings of 17th International Conference on Control, Automation and Robotics. Zurich.

UNECE (2012). Intelligent Transport Systems (ITS) for sustainable mobility. Geneva: UNECE.

Winkler, H. & Kuss, C. (2016). Sustainable Logistics and Strategic Transportation Planning. Using a Supply Chain Improvement System (SCIS) to Increase Supply Chain Efficiency (Sustainable Logistics and Strategic Transportation Planning). Hershey: Business Science Reference.

Xing-cai, L. et al. (2014). Synthetic Optimization Model and Algorithm for Railway Freight Center Station Location and Wagon Flow Organization Problem. Mathematical Problems in Engineering, 2014, 1-12. doi:10.1155/2014/