Real Time Scheduling of Data Transmission Sessions in a
Microsatellites Swarm and Ground Stations Network Based on
Multi-Agent Technology
P. Skobelev
1,3
, E. Simonova
1,3
, A. Ivanov
2
, I. Mayorov
3
, V. Travin
3
and A. Zhilyaev
1,3
1
Samara State Aerospace University, 34, Moskovskoye Shosse, Samara, Russia
2
École Polytechnique Fédérale de Lausanne, Route Cantonale, 1015 Lausanne, Switzerland
3
SEC “Smart Solutions”, Ltd, 17, Moscovskoe Shosse, office center “Vertikal”, office 1201, Samara, Russia
Keywords: Microsatellite, Ground Station, Multi-Agent Technology, Communication Session, Ontology, Data-Stream
Scheduling, Agent, Real Time.
Abstract: The problem of designing an effective models and methods for data transmission between group of
microsatellites and network of ground stations in the dynamically changing environment is considered.
Multi-agent technology for solving the problem by adaptive resource allocation and scheduling is proposed.
It is shown that solution of the considered complex problem evolutionary emerges from interaction and
trade-offs of many agents which continuously self-organize themselves and change decisions to improve
their objectives and the objectives of the system as a whole. The advantages of multi-agent solution are high
adaptability, flexibility and efficiency of services. The main classes of agents, ontology of problem domain,
interaction protocols, results of first experiments with system prototype and key benefits of proposed system
are discussed.
1 INTRODUCTION
Recent achievements in miniaturization of satellites
components made easy access to space for SME and
universities. As the result, a new class of satellites
called small-scale have appeared. The current
classification of such satellites has formed by their
weight characteristics: pico-satellites - under 1 kg,
nano-satellites - from 1 to 10 kg, microsatellites -
from 10 to 100 kg, mini-satellites - from 100 to 500
kg and small SC - from 500 to 1000 kg.
New trend of small satellites industry is
characterized by designing microsatellites swarms,
capable of continuous earth surface monitoring,
resolve navigation and telecommunication issues,
etc. The small satellites swarms can dramatically
change the market of space systems and provide new
low-cost services comparing to the ones that are
implemented today (Zinchenko, 2011, Global
Navigation Satellite Systems, 2012). On the other
hand, increased number of microsatellites in orbit
results in overload of management systems and the
necessity to process large amounts of target
information. Under these circumstances, a problem
of scheduling the timely data transfer from
microsatellites to the ground stations becomes one of
the most urgent.
In this paper the multi-agent technology for
solving the problem by adaptive resource allocation
and scheduling is proposed. It will be shown that
solution of the considered complex problem could
evolutionary emerge from interaction and trade-offs
of many agents which continuously change
decisions to improve their objectives and the
objectives of the system as a whole.
The paper is organized as follows. First part will
formalize the problem statement and give method of
scheduling based on multi-agent technology. The
second part will consider the architecture of multi-
agent system for problem solving including specific
classes of agents and protocols of their interaction.
The third part will present results of first
experiments with software prototype of the system.
At the end the key benefits of proposed system
and future steps will be discussed.
153
Skobelev P., Simonova E., Ivanov A., Mayorov I., Travin V. and Zhilyaev A..
Real Time Scheduling of Data Transmission Sessions in a Microsatellites Swarm and Ground Stations Network Based on Multi-Agent Technology.
DOI: 10.5220/0005034301530159
In Proceedings of the International Conference on Evolutionary Computation Theory and Applications (ECTA-2014), pages 153-159
ISBN: 978-989-758-052-9
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
2 PROBLEM STATEMENT
Let’s consider a swarm of microsatellites that
belongs to different types of users (e.g. several
universities, SME, ERS operators, etc.) and focused
on getting the information from microsatellites and
on data transceiving to the ground stations.
Microsatellites swarm functionality can change
in time (some of them break down, the new ones are
launched, etc.). Each microsatellite can have
constraints of technical, organizational, financial or
of any other character on the data transmission to the
ground stations that belong to different developers.
Therefore there is a group of available stations for
data transfer and the group of temporary available
stations. Let’s assume that all ground stations have
an ability to transmit the received information to
another station with the use of Internet. Data
transmission task is a task to transmit the specified
data amount from one particular microsatellite in a
given time period. Data transmission to the ground
station should be proceeded by a communication
sessions which need to be scheduled properly. It is
necessary for the implementation of some
preliminary work on the station, including the
computation of target destinations for antenna
aiming to a certain satellite, preparation of
engineering software tools for processing of
incoming information, etc.
The main idea of the suggested development is to
design a method of real time scheduling for
microsatellites data transmittion sessions to ground
stations system with dynamic constraints. Duration
of communication sessions between microsatellites
and ground stations is one of the key factors that
affect monitoring performance and data delivery
efficiency. Therefore, data delivery to the ground
stations optimization influences directly satellites
efficiency.
The main objective for sarm is to provide the
efficient data transmittion from microsatellites at the
required time with the minimum delay from the
moment of on-board data receipt. At the same time,
system should adaptively correct schedule for each
station, considering the unpredictable events:
failures on a satellite, station equipment failure, new
VIP user request on data receipt, etc. If unexpected
events have occurred on one of the stations, its tasks
should be redistributed between other stations of the
network.
The considered problem of data transmission
sessions scheduling between many microsatellites
and ground stations can be more formally
formulated in the following way. There must be
provided data flow Ф maximization in the
microsatellites system N on the time horizon T for
M stations:
,)()()( dttscheduletlinktrate
ij
M
j
N
i
T
ijij
11
0
(1)
where
)(trate
ij
is a speed of data transfer from
microsatellite i to ground station
j,
)(tlink
ij
is a
mutual data transfer efficiency from microsatellite to
ground station,
)(tschedule
ij
– duration of data
transfer between the i-th microsatellite and j-th
ground station, planned according to the intervals of
their mutual visibility.
Therefore, a solution of the above problem
requires coordinated real time scheduling of tasks in
the stations and microsatellites network.
3 MULTI-AGENT TECHNOLOGY
FOR PROBLEM SOLVING
Traditional centralized planning is based on classical
mathematical methods, for example, linear and
dynamic programming, discrete optimization,
constraint programming, etc.
But it is well-known that such type of problems
is NP-hard and that is why a number of a new
heuristic and metaheuristic scheduling models,
methods and algorithms appeared, such as greedy
methods and other various methods of local
optimization, neural networks and genetic
algorithms as well as other evolutional
computations, simulated annealing, tabu search, ant
search, mixed miscellaneous metaheuristics and
many others (Leung, J. YT. (ed .), 2004).
However, there is still a gap with the market
requirements because all orders and resources need
to be known in advance and processed in batch
mode which it is not a case in real life.
Multi-agent technologies allow to solve complex
problems evolutionary on the fly, according to new
unpredictable events coming in a real time
(Wooldridge, 2009, Rzevski, Skobelev, 2014).
In developed approach,system will receive orders
in real time as well as a flow of other unpredictable
events: order cancellations, unavailability of
resources, failures or delays etc.
The plan for resource usage has to be
dynamically formed and continuously and
adaptively revised taking into consideration
individual set of criteria, characteristics, preferences
and constraints of orders and resources. The full
ECTA2014-InternationalConferenceonEvolutionaryComputationTheoryandApplications
154
cycle of satellites and stations management must
include fast reaction to new events, allocation of
orders to resources, scheduling of orders/resources,
optimization of orders (if time is available),
communication with users, monitoring of plan
execution, re-scheduling in case of a growing gap
between the plan and reality.
The revision of the schedule must be made by
the allocation of operations to open time slots or by
solving conflicts between operations that can be
shifted to previously allocated resource or re-
allocated / swapped to the new resources.
Communication with users means supporting a
dialogue with the users via mobile phones or other
tools initiated by either side at any time.
The developed approach is based on a “holon”
concept of PROSA system (Brussel, 1998) where
specific classes of agents of “orders”, “products”
and “resources” were introduced as well as a “staff”
agent which monitors results and advises other
agents when required.
To make this approach more flexible and
efficient the concept of Demand-Supply Networks
(DSN) was introduced where agents of demands and
supply are competing and cooperating on Virtual
Market (VM). In the concept any agent (holon) of
physical or abstract entity can generate “small”
demand and supply agents, which follow the specific
requirements.
As a result, the schedule can be formed as a kind
of requirement-driven network of operations which
can be easily adapted by events in real time
(Skobelev, Vittikh, 2003, Skobelev, Vittikh, 2009).
The core part of the method of adaptive
scheduling can be identified as the following:
1. The number of classes of demand and supply
agents represents specifics of the problem
domain with the required level of granularity.
2. Satisfaction function and function of bonuses /
penalties are represented by linear combination
of multi-criteria objectives, preferences and
constraints of each agent.
3. Protocols are defined which specify how to
identify conflicts and find trade-offs with the
open slots, shifts and swaps of operations.
4. A schedule formed in the process of DSN
agents self-organization is based on decision-
making and interaction of agents.
5. Special event procession protocols are
triggered when new events occur (for example,
arrival of a new demand):
a. An agent is allocated to a demand as it
arrives into the system. The Demand
Agent sends a message to all agents
assigned to available resources stating
that it requires a resource with particular
features and it can pay for this resource
with a certain amount of virtual money.
b. All agents representing resources with
all or some specified features and with
the cost smaller or equal to the specified
amount of money, offer them to the
Demand Agent.
c. The Demand Agent selects the most
appropriate free resource from those on
offer. If no suitable resource is free, the
Demand Agent attempts to obtain a
resource, which has already been linked
to another demand, by offering to that
demand some compensation.
d. The Demand Agent who has been
offered some compensation considers
the offer. It accepts the offer only if the
compensation enables it to obtain a
different satisfactory resource and at the
same time increase the overall value of
the system.
e. If the Demand Agent accepts the offer,
it reorganises the previously established
relationship between that demand and
resource and search for a new
relationship with resource increasing the
overall value of the system.
f. The same process is running for
Resource agents which are able to
generate Supply agents with specific
context-based requirements.
6. The above process is repeated until all
resources are linked to orders and there is no
way for agents to improve their current state or
until the time available is exhausted.
To achieve the best possible results agents use
the virtual money that regulates their behaviour. The
amount of virtual money can be increased by getting
bonuses or decreased by penalties depending of their
individual cost functions. The key rule of the
designed VM is that any agent that is searching for a
new better position in the schedule must compensate
losses to other agents that change their allocations to
resources, and propagation of such wave of changes
is limited by virtual money (Skobelev, Vittikh,
2009).
Therefore, the final schedule is built as a
dynamic balance of interests (consensus) of satellites
and stations agents that negotiate for their position in
the network schedule and plan their work by shifting
and reallocating time slots with the view on their
objectives and interest of the whole swarm.
RealTimeSchedulingofDataTransmissionSessionsinaMicrosatellitesSwarmandGroundStationsNetworkBasedon
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155
4 MULTI-AGENT SYSTEM FOR
SESSIONS SCHEDULING
4.1 Architecture of the System
Architecture of multi-agent system for
communication sessions scheduling between
microsatellites and ground stations network is sown
in the Figure 1.
Figure 1: Architecture of multi-agent system for
communication sessions scheduling.
The key components of the system include:
• Physical Model – a simulation component that
is designed for Earth rotation simulation,
calculation of satellites orbits and visibility
intervals for microsatellites and ground
stations.
• Adaptive scheduler – scheduling system,
responsible for the forming and adaptive
change of the data communication sessions
schedule. Adaptive scheduler is based on the
multi-agent technology and is implemented in
Java Agent Development Framework (JADE)
according to FIPA standards for intellectual
agents (FIPA, 2014).
• Ontology provider – a component that allows
to formalize problem domain knowledge by
defining concepts and relation of the domain
area represented in a form of semantic
network;
• User Interface – provide possibility to make
settings and visualize results of scheduling.
All components are developed in Java.
4.2 Ontology of Small Satellites and
Ground Stations
An ontology is used to formalize the knowledge that
is necessary for the agents to take decisions.
According to our approach, knowledge should be
separated from the program code of the system and
kept in the ontology that represents a network of
concepts and relations of the problem domain area
(Huhns, 1997, Skobelev, 2012).
More specifically ontology in the developed
approach hels to specify requirements for satellities
and stations to make matching. Fragment of
ontology of small satellities and networks is shown
in the Figure 2 where it mainly includes
microsatellite, ground station and tasks scheduled
for the system.
Ontology helps to configure parameters of tasks,
microsatellites and ground stations and set the rules
of planning sessions between microsatellites and
ground stations.
Station
has
Schedule
Microsatellite
Сommunication session
expects
consists of (whole-part)
Priority Duration
Time interval
consists of (whole-part)
Start time End Time
visible in
Figure 2: Ontology fragment of the multi-agent system for
communication sessions scheduling.
According to this structure, each ground station
has individual schedule where planned
communication sessions with microsatellites and
station operation schedule are displayed. Each
communication session is characterized by priority,
duration, performance status and time period when it
need to be executed. Communication sessions can be
possible only in certain time intervals, during which
a direct visibility between a microsatellite and a
station is maintained.
4.3 Agents Functionality
Each ground station is associated with a resource
agent. Resource agent objective is to maximize
profit and schedule maximum of sessions with the
preference of own microsatellite tasks and providing
minimum idle run of the equipment.
Each communication session is associated with a
task agent. Task agent objective is to allocate to the
best ground station, which parameters fully satisfy
problem constraints with minimum costs. Task agent
can react to the events, addition/removal of ground
stations and tasks cancellations.
Satellite agent create session agents and is trying
Adaptive
scheduler
Ontology
provider
Physical
model
Ontology
User
Interface
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156
to maximize its own efficiency – to provide as much
useful information as possible.
To provide the economy-driven reasoning,
virtual market is introduced, where all decisions of
agents are linked with virtual money. Each agent has
an objective and bonus/penalty function.
The objective function represents satisfaction of
the agent depending on the achievement of the
objectives. Bonus/Penalty function sets a bonus for
achieving ideal target objectives or a penalty for
missing targets.
Each agent tries to maximize its satisfaction and
increases the profit (virtual money) that he can
spend for shifting other agents in the case of a
conflict, which he tries to resolve in the interests of
the system as a whole. Objective function of the
system is calculated as the sum of satisfaction of all
its existing agents (Figure 3(a)). Scheduling
problems is solved iteratively in evolution way by
the step-by-step increase (local improvement) of the
objective functions values of each agent.
When the task is initialized its agent gets the
initial sum of virtual money according to its priority.
This money can be used as a payment for allocation
on the chosen resource and for the compensation of
the expenses of the tasks shifted during the
allocation. Objective and penalty functions are built
considering time limits for the task agent and
considering the loading on the certain scheduling
interval fort the resource agent. T – time horizon,
KPI – key performance indicator (Figure 3 (b)).
KPI, %
F
0
1
20
T, hour
F
0
1
80
a) b)
Figure 3: An example of the task (a) and resource (b)
objective function.
The key rule of the designed VM is that any
agent that is searching for a new better position in
the schedule must compensate losses to other agents
that change their allocations to resources, and
propagation of such wave of changes is limited by
virtual money.
4.4 Agent Interaction Protocols
Scheduling process includes two phases which
continuously repeated:
1) Initial allocation of tasks to the resources
considering both preferences and time constraints;
2) Proactive improvement of tasks and
resources by their rescheduling.
Agent interaction protocol for the first phase is
shown in the Figure 4. This protocol is a
modification of Contract Net interaction protocol
implementation, specified by the FIPA standard.
Arrived task agent defines a list of available and
appropriate for the allocation resource agents and
then it sends a message-request CFP (Call for
Proposal) to each of the, which contains satellite
name and time interval, during which a
communication session should be scheduled.
Figure 4: First phase of agents interaction protocol in case
of a new task arrival.
Each resource agent that received this message,
forms a visibility intervals analysis in the specified
time slot. The calculations are only performed on
request, because visibility intervals calculation
between microsatellite and a station is a resourceful
operation. Then from the obtained list of the possible
task allocation intervals those time slots are
excluded during which station is busy according to
its schedule. If there are no time slots available for
allocation, resource agent sends a response “refuse”,
otherwise – message “propose” that contains a list of
the available intervals.
When resource agent receives an “accept-
proposal” message, it checks the specified
scheduling time slot for occupation by other tasks. If
the interval is free then a responding message
“inform” is sent, resource agents gets a payment for
the allocation and task information is recorded in the
schedule. Otherwise, a “failure” message is sent and
Task Agent
Resource Agent
m
CFP (satellite name, permissible slots )
n
refuse
i ≤ n
propose (list of available slots)
[there are no available slots for placing]
j = n - i
reject-proposal
j-1
accept-proposal (slot for placing)
1
failure
inform
[selected interval is not avai lable]
[task is scheduled]
Selection slot
RealTimeSchedulingofDataTransmissionSessionsinaMicrosatellitesSwarmandGroundStationsNetworkBasedon
Multi-AgentTechnology
157
when task agent receives it, it tries to be allocated on
the other resource.
Then an phase of proactive improvement of task
agent satisfaction is initiated. Task agent with the
smallest objective function value starts the
improvement process first. Proactive task asks the
appropriate resources, defining the allocation cost in
the different time slots.
Among the tasks already planned on this
resource, two tasks one on the left and one right side
of the slot are selected. Agents of these tasks receive
a request on shift on the specified time. Recursive
shifting of the tasks affected by the shift continues
until one of the tasks can move to the new position
without conflicts, the displacing task still have
means to compensate the expenses or a counter that
limits recursion depth equals zero. A process of
agent interaction when shifting the tasks in the
ground station schedule is shown in Figure 5 where
solid arrows represent messages with the shift
request and response messages of the shifted tasks
are shown as dotted lines.
t
Figure 5: Recursive task shifting.
From the set of possible allocation positions
those options are excluded, which confirmation will
not let to improve the system objective function
value, and the best option is chosen from the ones
that are left.
The task that remains unscheduled is out in the
list of tasks that wait for the scheduling. New
attempt of scheduling for these tasks will be made in
case of arising new events of adding new resources
or schedule changes of the existing ones.
The designed system implements models,
methods and algorithms that were earlier developed
for the multi-agent swarm of satellites (Sollogub,
2013), where the incoming tasks adaptively
reschedule tasks of satellites.
4.5 Example of Scheduling
Let us consider an example of communication
sessions scheduling for 5 ground stations.
In the traditional approach the data from
satellites will be transmitted only to their own
ground stations (Table 1). In these case the KPI of
all the involved stations is defined as the ratio
between the total data receipt time (~2720 sec) and
the length of the considered scheduling interval (24
hours) and it will be equal about 3%.
Table 1: Tasks allocation on its own stations.
Satellite Ground
Station
Sessions
number
Total
connection
time, sec
Data
volume,
Mb
CubeSat XI Kashima11 11 2200 2.64
HamSat Neustrelitez 17 3400 4.08
Mozhayets Kourou11 12 2400 2.88
ECHO Wallops14 15 3000 3.6
CubeSat V Malindi 13 2600 3.12
Total 16.32
With the use of multi-agent scheduling system
for the the same number of tasks it will be enough to
use only two stations. It allows not only to reduce
the maintenance cost of ground infrastructure and
increase stations KPI up to 20%, but also increases
the volume of transferred data from 16,32 to 20,64
Mb (with the data transfer speed 9600 bit/s).
Table 2: Communication sessions scheduling with stations
of the network.
Satellite Ground
Station
Sessions
number
Total
connection
time, sec
Data
volume,
Mb
CubeSat XI
Kashima11
Neustrelitez
11 3000 3.6
HamSat 17 4600 5.52
Mozhayets 12 2800 3.36
ECHO 15 3600 4.32
CubeSat V 13 3200 3.84
Total 20.64
Volumeincrease of the data transferred from the
satellite is shown in the Figure 6 that is achieved by
communication sessions scheduling in the network
of ground stations, comparing to the traditional
approach.
The results is showing the high value which
could be provided by bio-inspired models and
methods for real time scheduling based on
fundamental principles of self-organization and
evolution.
Figure 6: Transferred data volume.
ECTA2014-InternationalConferenceonEvolutionaryComputationTheoryandApplications
158
Next steps in the R&D work will be focused on
industrial version of the solution for modeling EU
Cubsat50 program and other applications.
5 CONCLUSIONS
The papers presents developed approach for
adaptive scheduling of data transmission sessions for
group of small satellites and ground stations.
It is shown that solution of the considered
problem evolutionary emerges from interaction and
trade-offs of many agents which continuously self-
organize themselves and change decisions to
improve their objectives and the objectives of the
system as a whole.
The advantages of developed multi-agent
solution are high adaptability, flexibility and
efficiency of future satellite services.
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