Modules FAQ
Why develop a module for an application?
What is the patented "Monitor, Detect, Action"
process?
What are some possible variables that a module can monitor?
What is involved in the detection phase?
What are some examples of actions that can be taken?
How can NEL Frequency Controls add value to a project?
Is there a cost benefit to using modules?
What does NEL's experience include?
Why develop a module for an application?
Many complex, high-speed, multifunction systems require an appropriate
response to environmental or internal changes quickly. Correlation between
the physical or environmental characteristics being monitored and the
circuit parameters must be determined to generate an appropriate response.
The modules are designed to do this quickly, while limiting the product
designer's concern to the inputs, outputs and actions that are required.
What is the patented "Monitor, Detect, Action"
process?
An appropriate response to internal or environmental changes require three
actions to occur within a critical time frame.
•Monitor: The system must
first monitor the primary input signals for changes.
•Detect: Then the
system must detect whether those changes exceed predetermined limits (limits
can be variable depending on current conditions).
•Action: Lastly, action
must be taken. The action can be as simple as notifying the system or
operator of the status through a signal or indicator. Alternatively, the action could consist of making intelligent decisions based on multiple
detector information.
What are some possible variables that a module
can monitor?
• Frequency - The system could watch for the presence of a signal
source such as if a clock fails and has no frequency output. On the other
hand it could monitor for a frequency source to be out of tolerance. This
can occur when an oscillator fails to start properly.
• Current or Voltage - Monitoring a "hot swappable" device
or component for current or voltage could help the system determine whether
the item has been removed or is installed. If it is removed it will cease
to draw current and it will begin again once it is replaced. The current
or voltage levels could also be monitored to determine when lower or upper
limits are met or exceeded.
• Motor Speed - When a device starts, stops, slows down or speeds
up could also be determined by the monitoring system. The system could
determine when upper or lower limits for speed or acceleration are met
or exceeded.
• Position - Both rotational and linear position could be monitored.
Rotational shaft positions can be determined for less than a 0†10' change
in the angle. Linear position could also be determined using a conversion
from rotational information.
What is involved in the detection phase?
The detection phase processes the information from the monitoring methods
that have been selected. Detection would determine whether they pass,
fail or meet other criteria that requires action.
Microcontrollers can serve many of these purposes today. But the signal must be in a digital form if it is not already. This can be done using an analog/digital conversion or analog comparitors. Analog comparitors detect analog limits using the reference voltage as a limit voltage for the application.
What are some examples of actions that can be
taken?
• Reporting - Making the system or the operator aware of the conditions
that have been detected is the simplest action. This might include simply
setting a digital bit high or low to indicate a change or lighting an
LED to indicate to an operator that the status has changed. A report to
the system may also consist of a more complex digital signal.
• Switching - The action could cause the system to switch to alternate
or backup sources if a device fails or its condition changes. The system
could also switch off the failed device or switch on another device.
• Adjustments - If certain criteria are detected the system could
make changes to any number of outputs including motor speed, rotational
position, frequency or amplitude.
How can NEL Frequency Controls add value to a
project?
The module concept allows our engineers to develop plug and play devices
for your applications. You will not have to worry about any engineering
considerations for capturing inputs and configuring outputs and actions.
You just let us know what the inputs and action thresholds are along with
what actions need to be taken and we take care of the details.
We currently have a patent pending for the control loop sensing upon which "Monitor, Detect, Action" systems are built. Our engineers have vast experience with creating high reliability frequency control devices and motion control encoders. Our work in these areas has included numerous miniaturization and signal conditioning projects. This experience allows us to build mission critical control systems for almost any requirements.
Is there a cost benefit to using modules?
Yes. By allowing NEL to use their vast experience, your engineers and
design team will not spend time on research and development of the steps
between inputs, outputs and actions. They just have to determine what
these are.
What does NEL's experience include?
Our past experience includes a range of monitor, detect, action and other
applications:
• Mixed signal knowledge - We have worked with and interfaced between
many different digital technologies, analog signals, RF signals, and microwave
signals o RF, analog and EMI filtering
• Noise source generation - generating noise sources for controlled
noise injection
• Reliability Quality issues - HALT concepts, FIT rate calculations,
long term aging affects, moisture levels and cleanliness/contamination
issues
• Reliability Physics - Electronic component failure mechanisms Detect
o Frequency domain and time domain relationships
• Control loops - phase locked loops, motor control loops, microcontroller
• Encoder technologies - absolute and incremental, optical and hall
affect, digital or analog outputs
• Redundancy concepts for mission critical applications
• Quartz
crystal design and processing
• Oscillator design and manufacture
• Hybrid electronic packaging including hermetic seal, ceramic and
glass to metal packaging.
• Signal integrity applications such as transmission lines, impedance
matching, jitter issues and phase noise issues.
• Miniaturization - We commonly work with extremely small size components
and creative packaging to miniaturize circuits. Some standard components
we have worked with are bare IC DIE, thick film resistors to reduce overall
size 0402 chip components. IC DIE stacking to save space is one example
of our creative packaging solutions