WebNMS has announced end-of-life for the WebNMS Simulation Toolkit as
detailed on their site as of December 31, 2019.
For customers requiring the latest features of an SNMP simulator we offer half off
on an upgrade to the latest version of MIMIC Simulator (ie. 50% discount)
until March 31, 2020.
Take advantage of a first-class simulation environment geared towards large-scale,
custom, rapid development, testing, prototyping, demonstration of network management
applications. For more details, see the videos on our Youtube channel or contact us at
sales@gambitcomm.com .
Monday, January 13, 2020
Wednesday, October 30, 2019
MIMIC MQTT Simulator integrates with Alibaba IoT Platform
We have added MIMIC MQTT Simulator integration with the
Alibaba IoT Platform for getting started, evaluation, development,
testing and proof-of-concept on this platform.
Here a simulated sensor is updating its device shadow:
Alibaba IoT Platform for getting started, evaluation, development,
testing and proof-of-concept on this platform.
Here a simulated sensor is updating its device shadow:
Thursday, October 17, 2019
Dynamic, real-time, predictable testing of Amazon Greengrass
Efficient testing of Amazon IoT Greengrass with lots of devices is difficult to
achieve, unless you use simulation techniques as everywhere else in
engineering.
We setup a lab of 100 simulated sensors in MIMIC MQTT Simulator
publishing telemetry in real-time to one instance of Greengrass, simulating
an IoT edge scenario where telemetry is processed at the edge, without
needing to go to the cloud. Most of the telemetry is uninteresting, unless an
anomaly occurs, such as a temperature value above a certain threshold.
In this 2-minute Youtube video 10 of those sensors are started, and monitored
by a subscriber application based on NODE-RED. You can see how it
tracks the temperature and light values of the sensors. We dynamically
and predictably create the anomaly in a matter of seconds.
Then we expanded the number of active sensors to 100, but the NODE-RED
application would not easily show the number of sensors on the graph
(even 10 cannot be definitively shown, and 100 hung the app).
So, we wrote a small Python MQTT subscriber client, which monitors each
sensor reported at the Greengrass local shadow, and displays the number
of sensors detected, and whether any of them exceeds the arbitrary
threshold (our anomaly).
This 2-minute Youtube video shows the interesting parts of the setup,
and the successful completion of the test.
When testing with Greengrass, make sure to use MQTT simulation to
verify your application.
achieve, unless you use simulation techniques as everywhere else in
engineering.
We setup a lab of 100 simulated sensors in MIMIC MQTT Simulator
publishing telemetry in real-time to one instance of Greengrass, simulating
an IoT edge scenario where telemetry is processed at the edge, without
needing to go to the cloud. Most of the telemetry is uninteresting, unless an
anomaly occurs, such as a temperature value above a certain threshold.
In this 2-minute Youtube video 10 of those sensors are started, and monitored
by a subscriber application based on NODE-RED. You can see how it
tracks the temperature and light values of the sensors. We dynamically
and predictably create the anomaly in a matter of seconds.
Then we expanded the number of active sensors to 100, but the NODE-RED
application would not easily show the number of sensors on the graph
(even 10 cannot be definitively shown, and 100 hung the app).
So, we wrote a small Python MQTT subscriber client, which monitors each
sensor reported at the Greengrass local shadow, and displays the number
of sensors detected, and whether any of them exceeds the arbitrary
threshold (our anomaly).
This 2-minute Youtube video shows the interesting parts of the setup,
and the successful completion of the test.
When testing with Greengrass, make sure to use MQTT simulation to
verify your application.
Monday, October 14, 2019
Anomaly detection scenario with Google IoT Core
The traditional anomaly detection scenario involves detecting unusual
behavior in a vast sea of normal data. To empirically test your anomaly-
detection IoT application requires you to setup a large environment of
sensors sending data to your Google Pubsub application.
To do this in real-time to verify response time constraints is specially hard
to do.
To demonstrate how simulation can simplify this task, we improved on the
Google Cloud IoT Core End-to-end example tutorial by making 10 lines of
code change to their pubsub Python server code.
The changes merely count the number of devices detected (by their
serial number), and the anomaly is detected if any temperature value
exceeds the threshold, printing a WARN message.
When we start 10 simulated sensors in MIMIC MQTT Simulator configured
to connect to Google IoT Core, they are detected by the listening Pubsub
application. We can then change in real-time the temperature of one of them,
causing the pubsub application to detect the exceeded threshold.
This 1-minute Youtube video shows the entire demo in real-time.
We then used their Python manager client to define 90 more devices for
a total of 100. Then we ran the same scenario again. Notice the lag between
when the event occurred and the detection by the Pubsub application.
Here we show the entire demo in this 1-minute Youtube video.
behavior in a vast sea of normal data. To empirically test your anomaly-
detection IoT application requires you to setup a large environment of
sensors sending data to your Google Pubsub application.
To do this in real-time to verify response time constraints is specially hard
to do.
To demonstrate how simulation can simplify this task, we improved on the
Google Cloud IoT Core End-to-end example tutorial by making 10 lines of
code change to their pubsub Python server code.
The changes merely count the number of devices detected (by their
serial number), and the anomaly is detected if any temperature value
exceeds the threshold, printing a WARN message.
When we start 10 simulated sensors in MIMIC MQTT Simulator configured
to connect to Google IoT Core, they are detected by the listening Pubsub
application. We can then change in real-time the temperature of one of them,
causing the pubsub application to detect the exceeded threshold.
This 1-minute Youtube video shows the entire demo in real-time.
We then used their Python manager client to define 90 more devices for
a total of 100. Then we ran the same scenario again. Notice the lag between
when the event occurred and the detection by the Pubsub application.
Here we show the entire demo in this 1-minute Youtube video.
Wednesday, August 28, 2019
Guard your IoT Application against hackers using IoT Simulation
The Internet of Things opens up many vectors for security vulnerabilities
as detailed in RFC 8576.
Vulnerabilities in all stages of a IoT device's life cycle include malware baked in
during manufacturing, or patched while operating by exploiting zero-day
vulnerabilities, specially after the manufacturer's support of the old device is
discontinued (end-of-life). This malware usually causes the IoT device to
deviate from its intended function for some nefarious purpose.
Part of any IoT Testing and Proof of Concept (PoC) includes addressing security
concerns by adding security monitoring solutions to prevent intrusions,
malware, etc in order to prevent the high failure rates of IoT projects.
While preventing malware through authentication, authorization and privacy is
a first defense, the IoT monitoring solution should detect behavior that is not
"normal". A usual test scenario then consists in reproducing cases of IoT devices
that deviate from their expected behavior. Unless you have a lab full of hacked
devices, this is not easy to do.
An IoT Simulator such as MIMIC IoT Simulator is designed to easily recreate
scenarios meant to test your IoT monitoring solution for common hacking
scenarios, such as misbehaving IoT devices (eg. hacked devices sending unusual
Internet traffic, or accessing unauthorized resources), incorrectly configured
firewall or load-balancing rules, reported common vulnerabilities and exposures
(CVE) such as in this article .
The "normal" behavior of an IoT device can be characterized by the network
traffic it emits and the resources it accesses. Monitoring solutions can learn
this behavior and alert if it deviates from this pattern. MIMIC can control any
simulated device to behave differently at any point in time, and can easily create
different behaviors on demand. Thus, the monitoring solution can be exercised
to prove that it handles certain scenarios, such as higher traffic rates, network
traffic to different destinations and access to restricted resources. Since the
simulator creates reproducible scenarios, it can be part of regression tests
supporting an agile development cycle.
For example, this Youtube video demonstrates complete, dynamic, real-time
control of message generation rates in MIMIC.
as detailed in RFC 8576.
Vulnerabilities in all stages of a IoT device's life cycle include malware baked in
during manufacturing, or patched while operating by exploiting zero-day
vulnerabilities, specially after the manufacturer's support of the old device is
discontinued (end-of-life). This malware usually causes the IoT device to
deviate from its intended function for some nefarious purpose.
Part of any IoT Testing and Proof of Concept (PoC) includes addressing security
concerns by adding security monitoring solutions to prevent intrusions,
malware, etc in order to prevent the high failure rates of IoT projects.
While preventing malware through authentication, authorization and privacy is
a first defense, the IoT monitoring solution should detect behavior that is not
"normal". A usual test scenario then consists in reproducing cases of IoT devices
that deviate from their expected behavior. Unless you have a lab full of hacked
devices, this is not easy to do.
An IoT Simulator such as MIMIC IoT Simulator is designed to easily recreate
scenarios meant to test your IoT monitoring solution for common hacking
scenarios, such as misbehaving IoT devices (eg. hacked devices sending unusual
Internet traffic, or accessing unauthorized resources), incorrectly configured
firewall or load-balancing rules, reported common vulnerabilities and exposures
(CVE) such as in this article .
The "normal" behavior of an IoT device can be characterized by the network
traffic it emits and the resources it accesses. Monitoring solutions can learn
this behavior and alert if it deviates from this pattern. MIMIC can control any
simulated device to behave differently at any point in time, and can easily create
different behaviors on demand. Thus, the monitoring solution can be exercised
to prove that it handles certain scenarios, such as higher traffic rates, network
traffic to different destinations and access to restricted resources. Since the
simulator creates reproducible scenarios, it can be part of regression tests
supporting an agile development cycle.
For example, this Youtube video demonstrates complete, dynamic, real-time
control of message generation rates in MIMIC.
Monday, June 17, 2019
MIMIC SNMP SImulator and Prometheus FOSS
We installed the Prometheus free open-source software NMS, and enabled
SNMP monitoring following this post.
Once we pointed Prometheus at a out-of-the-box 25-node simulated network with
MIMIC SNMP Simulator
we can monitor network interfaces. The graphing can be
compared to a commercial offering as shown below:
SNMP monitoring following this post.
Once we pointed Prometheus at a out-of-the-box 25-node simulated network with
MIMIC SNMP Simulator
we can monitor network interfaces. The graphing can be
compared to a commercial offering as shown below:
Friday, June 14, 2019
IoT Control System at the edge: MIMIC MQTT Simulator and AWS IoT Greengrass
Overview
AWS IoT Greengrass is Amazon's IoT edge processing platform. We used theirdocumentation and other sources [1] with MIMIC MQTT Simulator to setup a
simple control system at the edge to test bi-directional MQTT message flow
(from sensors to control logic, and from control logic to actuator).
For those who'd rather skip to the video, here is the 2-minute Youtube video.
This example illustrates the purpose of IoT at the edge: the processing that does
not need the cloud should happen locally. In this test, everything is occurring at
the edge, we just added device shadow synchronization to the AWS IoT cloud
for illustration.
Details
You need to setup an account at Amazon AWS IoT. Once logged into the AWS IoTconsole, and a Greengrass Group has been created according to their
Getting Started manual. We setup a group called GG_group2 with a core
GG_group2_Core.
Then we simulated our usual bi-directional simple control system at the edge,
with these devices
including a sensor sensor_1 reporting telemetry to Greengrass core,
running in MIMIC as seen above on the left, with certificates as configured in
AWS on the right.
When the actuator (eg. cooling system) in the control system is off, the sensor
temperature heats, and when it is on, then it cools. We implemented the control
system logic in a Node-RED flow, rather than in a Lambda function.
It turns the actuator on if the temperature exceeds a high threshold, and turns it
off if the temperature is cool enough. The connectivity to the core broker is setup
as a subscriber to the shadow updates as shown below on the right:
and the Node-RED subscriber is configured to connect to the broker at the edge:
with TLS certificates exported by AWS:
The parts of the system need permission to publish as defined in the Greengrass
subscriptions:
Once everything is setup, the control system reaches a normal steady state at the
edge, as visualized by the Node-RED graphing rules, as shown in this 2-minute
Youtube video.
Conclusion
We saw that by using MIMIC MQTT Simulator we can create a real-timescalable, predictable, customized IoT Edge Control System scenario that
compresses the state transitions into a period short enough for showing in
less than 3 minutes.
Future work can improve on this to make it more scalable, test exceptions
(eg. what if the sensor does not cool down when fan is on?), test different
implementations (eg. Lambda function vs. Node-RED), etc.
References:
[1] The Hitchhikers Guide to AWS IoT
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