Dms Classic Analogue Waves

The main differences between the non-storage, non-digital analog 2200 series are as follows: the 2200 series is mostly 2 channel, with 2245, 2246, 2247, and 2252 being the 4 channel exceptions (the two extra channels having only two vertical attenuation values). The 2335 and 2336 are 2 channel, ruggedized versions mostly made for the military. Upload a Screenshot/Add a Video: Now you can add videos, screenshots, or other images (cover scans, disc scans, etc.) for TimeSplitters - Future Perfect (USA) to Emuparadise. All (except DMS-RP25) DMS-05 DMS-10 DMS-25 DMS-RP25 5cm or 5% whichever is greater 0.05° 0.10° 0.25° 0.25° (period 0 to 20s) Maximum range ±10m ±60° Bandwidth 0.05 to 30 Hz 0 to 30Hz Data output rate Digital: up to 200 Hz; Analogue: up to 500 Hz (with an external repeater) Available output parameters Adjustable data packet output rate.

Sound- mechanical energy transmitted through a medium.
Wave (Acoustic Waves)- a traveling variation in acoustic variables.
- a traveling variation in one or more quantities such as pressure
-Sound is a traveling variation in pressure, a wave. A longitudinal mechanical wave.
Temperature,Pressure, Density, Particle Motion (distance)
Density-Concentration of mass in a volume
*more about acoustic variables under amplitude & Intensity*
Propagation- transmittal to distant regions remote from the sound source.

Vacuum- a space void of matter. Matter is anything that has mass and takes up space.

Sound cannot travel in a vacuum. Electromagnetic radiation, light/x-ray can travel through a vacuum! Sound waves are not electromagnetic radiation.

Electromagnetic vs. Mechanical Waves

-Electromagnetic waves do not need a medium for travel.Mechanical waves travel through a medium and cause particle motion of the medium.
Electromagnetic Radiation- consists of alternating electrical and magnetic fields that are at right angles to each other and propagate through a vacuum at the speed of light.
Dms Classic Analogue Waves

Mechanical waves

-require a elastic deformable medium for propagation. This can be gas, liquid, or solid.
-cause motion of the particles they are moving through
- molecules do not travel from one end to the other it is not a flow of particles. Molecules vibrateback and forth.

Dms Classic Analogue Waves Serum

-can be either Transverse or longitudinal.

Longitudinal Waves (mechanical)

-propagates by particles of medium vibrating/moving in the same direction (along) the wave propagation direction.*it’s the particles of the medium that are moving*
Dms
-Those in which particle motion is along the direction of the wave energy propagation. The molecules vibrate back and forth in the same direction as the wave is traveling.

-sound is a mechanical longitudinal wave

Transverse Waves/Shear Waves/Stress Waves (mechanical)

-propagates by particles of the medium moving perpendicular (across) the wave propagation direction. *particles of medium are what are moving*
- Those in which the motion of particles is perpendicular to the direction of propagation of the wave energy.
-**The only biological tissue that can cause the production of transverse waves is BONE**

Important Terms Describing Sound Waves/The Properties of Sound

Compression- a high pressure region of the wave form. The area of maximum particle density. Also called Compression zone, Peak, Up-hump, Wavefront, Leading edge/Leading portion of a wave.

Rarefaction- a low pressure region of the wave form. The area of minimum particle density. Also called a Trough.

Cycle-one high pressure and one low pressure region of a wave.One complete variation in pressure or other acoustic variable.
- a sequence of changes in molecular motion that recurs at regular intervals.
- periodic changes in the pressure of a medium/sequence of changes in amplitude that recur at regular intervals.

Frequency (f) - The number of cycles that occur in one second; measured in MHz, kHz or Hz

-The number of particular events that occur in a specific duration of time.
- The number of vibrations that a molecule in a wave makes per second.
- The number of times the cycle is repeated per second.
-The number of pressure oscillations (cycles) occurring at a given point in one unit of time. (usually 1 sec.)

(F=1/p)frequency=1/period. or (F= c/λ ) frequency= propagating speed/wavelength

Hertz (Hz) - the unit of measurement for frequency. One cycle per second. Hertz= cycle/second

MHz-1,000,000 cycles/secondor kHz-1,000 cycles/sec

Diagnostic ultrasound frequency Range= 1-16MHz or 1-16 million Hz. 2-10 MHz some 2-16MHz
Period (T)-the time it takes for one cycle (complete pressure variation) to complete itself; measured in seconds(s) or microseconds (us)
Analogue
- The time between two successive compression zones or rarefaction zones.

(T=1/f )Period=1/frequency

- frequency is important in diagnostic ultrasound because it affects penetration and image quality.
- The dependence of other physical parameters on frequency is called dispersion.
Wavelength (λ) - The distance or length one cycle takes up; measured in meters(m), centimeter (cm), or millimeter (mm).
- The distance between two successive density zones.

λ=c/fwavelength= Propagating speed/frequency

-wavelength and frequency are indirectly related. If frequency goes up wavelength goes down.
-The only parameter determined by both sound source and the medium.
Propagation- Changes in pressure conveyed from one location to another.
- The transmittal to distant regions remote from the sound source.
Propagating Speed (P.S. or c)/Acoustic Velocity/Velocity of Sound- The speed thru which sound moves through a medium; measured in mm/us or m/s.
- The speed at which a wave propagates through the medium.
*remember velocity of sound and particle velocity are NOT the same thing!* Particle velocity-the speed at which the particles vibrate back and forth across their mean positions.*

-Determined only by the medium through which it travels.Specifically the density and stiffness of the medium.

-Not operator adjustable

-Thru soft tissue 1.54mm/us or 1540 m/s

-Density and propagating speed are indirectly related so….If Density (D) increases propagating speed(c) decreases.

oDensity (D)↑ Propagating Speed (c)↓

-Stiffness and Propagating Speed are directly related so….If Stiffness increases propagation speed( c ) increases

o Stiffness↑ Propagating Speed (c)↑

* So materials that are very stiff but not dense will have the highest propagating speed.

*Materials that are not very stiff but are extremely dense will have the lowest propagating speed.
Properties of the medium that effect Propagating Speed
Elasticity-the ability of an object to return to its original shape and volume after a force is no longer acting on it. Force applied to an object cause a change in its shape or volume (distortion). The strength of the force determines the amount of distortion.
Ultrasound waves cause elastic deformation by the separation and compression of neighboring molecules. (particle velocity)
Density(d)- The mass of a medium per unit volume.
d=m/v
- larger mass requires more force to cause motion...and more force to stop molecules already in motion.
Particle density is not constant at a particular position but fluctuates with a time dependence imposed by the frequency of the sound wave.

-Density and propagating speed are indirectly related so….If Density (D) increases propagating speed(c) decreases.

Stiffness (s)/ Bulk Modulus- an objects ability to resist compression. The negative ratio of stress (force or pressure applied) and strain (change in volume). Stiffness is the inverse of compressibility.
-stiffness and propagating speed are directly related.
Compressibility (K) - The fractional decrease in volume when pressure is applied to the material.
- so as stiffness increases compressibility decreases and acoustic velocity increases.
The source is able to determine the Period (T), Frequency (f), Amplitude, Power, and Intensity.
The source does not determine the Propagating Speed(c) *the medium does. Frequency is not related to propagating speed because propagating speed is a constant in soft tissue.
Wavelength (wavelength=c/f) is determined by both the medium and the source.
Pulse “A Burst of Cycles”- collection/group of two or more cycles followed by a resting time. We use pulsed waves for diagnostic ultrasound.

Pulse Duration (PD) -The amount of time from the beginning to the end of a single pulse of ultrasound.The time it takes for one pulse to occur*excludes the resting time*; measured in (us)

PD=nTPulse Duration= number of cycles x Period (time of one cycle)

Serum

-Pulse duration is not operator adjustable

Pulse Repetition Period (PRP) - The amount of time from the start of one pulse to the start of the next pulse. *includes resting time, sound on and off time*; measured in us

PRP= 1/PRF

-operator adjustable & determined by sound source

-unrelated to period

Pulse Repetition frequency (PRF) - The number of pulses that occur in a single second; measured in MHz or Hz

PRF=1/PRP

PRF and imaging depth are indirectly related so…imaging depth decreases PRF increases.Imaging depth increases PRF decrease.

PRF is operator adjustable.

Spatial Pulse Length (SPL) - the length of space over which one pulse occurs; measured in mm.

SPL=n x λ Spatial pulse length= number of cycles x wavelength

-Spatial pulse length and frequency.If wavelength increases SPL increases. If wavelength decreases SPL decreases.

-If frequency increases than wavelength decreases so if frequency increases SPL decreases

-shorter pulses=better images

Duty Factor (DF) - The fraction of time that pulsed ultrasound is on.It compares on and off time; unit less

DF=PD/PRP can make a percent if multiply by 100.

-for sonographic systems it averages between .2%-.5%

-If PRP increases than DF decreases.If PRP decreases than DF increases.

-If PRF increases PRP decreases so if PRF increases DF increases.*f and f are alike*
Infrasound-a frequency of less than 20Hz.A sound frequency too low for human hearing. (below)

Audible Sound- 20-20,000HzThe range of human hearing.

Ultrasound- 20,000Hz or higher. A sound frequency too high for human hearing. (beyond)

Dms Classic Analog Waves

ultrasound- high frequency mechanical waves that humans cannot hear!

Dms Classic Analogue Waves Serum

**remember kilo (k)=1,000 and mega (M)=1,000,000** so 20 kHz is 20,000 Hz...ultrasound
Many electric distribution organizations are presently evaluating their approach to integrating three key operational systems – SCADA (Supervisory Control and Data Acquisition), OMS (Outage Management System) and DMS (Distribution Management System). SCADA, which has long been prevalent throughout transmission systems, is finding increased applications on distribution systems. Modern OMS, utilizing GIS-based connectivity models, is now well established and a key component of many organizations’ outage management business processes. The implementation of DMS functionality is a relatively recent trend. While a DMS can include and improve the traditional outage management functions, a DMS also typically includes applications that assist in the improved operation of the electric distribution system, as well as functionality for improving planned work on the system. This article first reviews SCADA, OMS, and DMS systems. Considering that both OMS and DMS require a connectivity model of the distribution system, the benefits of integrating OMS and DMS are presented. Next, the integration of SCADA with DMS/OMS is discussed, including the functionality of the integration and the resulting benefits. Finally, a proposed architecture for an integrated distribution operations center is presented.

Dms Classic Analogue Waves

SCADA
SCADA systems are globally accepted as a means of real-time monitoring and control of electric power systems, particularly generation and transmission systems. RTUs (Remote Terminal Units) are used to collect analog and status telemetry data from field devices, as well as communicate control commands to the field devices. Installed at a centralized location, such as the utility control center, are front-end data acquisition equipment, SCADA software, operator GUI (graphical user interface), engineering applications that act on the data, historian software, and other components.
Recent trends in SCADA include providing increased situational awareness through improved GUIs and presentation of data and information; intelligent alarm processing; the utilization of thin clients and web-based clients; improved integration with other engineering and business systems; and enhanced security features.
Outage Management Systems
Modern computer-based OMS, utilizing connectivity models and graphical user interfaces, has been in operation for some time now. OMS typically includes functions such as trouble-call handling, outage analysis and prediction, crew management, and reliability reporting. Connectivity maps of the distribution system assist operators with outage management, including partial restorations and detection of nested outages.
In recent years, OMS has become more automated. Outage prediction – the process of analyzing outage events such as trouble calls, AMI outage notifications, and SCADA-reported status changes – has improved. Interfaces to Interactive Voice Response systems (IVR) permit trouble call entry into an OMS without call-taker interaction and also permits the OMS to provide outage status information to customers and provide restoration verification call-backs to customers who request them.
OMS systems have also become more integrated with other operational systems such as Geographic Information Systems (GIS), Customer Information Systems (CIS), Work Management Systems (WMS), Mobile Workforce Management (MWM), SCADA, and AMI. Integration of OMS with these systems results in improved workflow efficiency and enhanced customer service.
Today’s OMS is a mission-critical system. At some utilities, it can be utilized simultaneously by hundreds of users. It integrates information about customers, system status, and resources such as crews, providing a platform for operational decision support.
Distribution Management Systems
In comparison to OMS, DMS functionality is relatively new. While DMS applications are utilized in outage management processes, DMS also extends to the efficient management of planned work and normal electrical operations. DMS is also typically associated with receiving real-time status and analog points from the distribution system, and the generation of supervisory control commands to distribution breakers, switches and reclosers, switched capacitor banks, voltage regulators, and load tap changers (LTCs). The importance of DMS will increase as additional amounts of customer generation, energy storage, and demand response are placed on distribution systems.
DMS is receiving a lot of attention because it can provide solutions to many challenges distribution organizations face today. Table 1 below contains a listing of DMS applications, functionality and benefits.
Integration of OMS and DMS
Integrated DMS/OMS provides a number of benefits to the distribution organization, as discussed below.
1. Integrated DMS/OMS Improves Operator Efficiency
An integrated DMS/OMS assists operators in performing their responsibilities better, compared to separate DMS and OMS systems. Displays have the same appearance and can provide a single intuitive interface for navigation. Additional displays for separate systems are not required in already-crowded operator workspaces. Operator training is minimized, since operators only need to learn the features of one GUI.

2. Integrated DMS Applications Improve the Outage Management Process
The integration of DMS applications in the OMS has proven to improve outage performance. For example, a fault location algorithm uses the as-operated electric network model, including the location of open switches, along with an electrical model of the distribution system with lengths and impedances of conductor segments, to estimate fault location. The DMS Fault Location functionality therefore uses the electrical DMS model, but ultimately improves the OMS process. The experience of Progress Energy Carolinas with the ABB Fault Location application shows a significant reduction in SAIDI over the 6 years since the application has been in operation.
Similarly, a Restoration Switching Analysis application evaluates the possible isolation and restoration switching actions that can be done upon occurrence of a permanent fault. The application executes an unbalanced load flow to determine overloaded lines and low-voltage violations for each switching action, and the operator is provided with a listing of recommended switching actions. Again, the functionality utilizes the DMS model of the system, but improves the Outage Management process and reduces CAIDI and SAIDI.
3. DMS/OMS Integration Improves Coordination of Planned and Unplanned Work
Distribution systems are dynamic in nature, with changes occurring on a daily basis due to both planned work and outage restoration. If a safe and efficient operation of the system is to be achieved, then it is critical to ensure that the current state of the network is continuously maintained and made available to those working on planned and unplanned work. This includes operators, dispatchers, persons responsible for switching requests and switching plans, field crews, engineering, and others who require an accurate representation of the system state.
Temporary network changes such as line cuts and jumpers, phase jumpers, switch operations, protective device operations, grounding tags, safety, warning, and information tags, and temporary generators should be represented. This is easiest if a single model is used for the DMS and OMS.
With DMS and OMS working with the same operational model of the distribution system, circuit analysis can be fully functional considering temporary changes. This includes circuit tracing, trouble call and outage analysis, safety interlocks, loop and parallel source detection, fault location and load flow. The result is a more comprehensive and accurate understanding of system conditions at any moment in time.
4. DMS/OMS Integration Reduces Data Maintenance Efforts
Many distribution organizations maintain and make planned updates to the network model in their Geographic Information System (GIS). Since DMS and OMS both require a connectivity model of the distribution system, data maintenance processes are simplified if the DMS and OMS are operating from the same model. The result is one set of processes for managing the network model, and one process for the incremental update to the DMS/OMS model instead of two.

Integration of SCADA and DMS/OMS
Integration of DMS/OMS with SCADA is an increasing trend. While the inclusion of SCADA “breaker-open” operations in OMS have long been used for outage detection, recent business challenges have driven a more comprehensive integration between the two systems. Available functionality now includes the transfer of status/analog points from SCADA to the DMS/OMS; the sending of supervisory control and manual override commands from the DMS/OMS to the SCADA; an integrated user interface running on the same operator console, and integrated single sign-on for users.
The benefits of integrating SCADA with DMS/OMS include:

  • Improved operations by close integration of DMS applications with distribution SCADA
  • Increased operator efficiency with one system, eliminating the need to go to multiple systems with potentially different data
  • Integrated security analysis for substation and circuit operations to check for tags in one area affecting operations in the other
  • Streamlined login and authority management within one system
  • One network model for OMS and DMS analysis
  • Consolidated system support for DMS/OMS and Distribution SCADA
  • Simplified data engineering via coordination of SCADA point and GIS data changes

Integration of SCADA and DMS/OMS can be between systems of the same vendor, or between different vendors, using a protocol such as ICCP (Inter-Control Center Communications Protocol). Using systems from the same vendor typically results in increased functionality and can reduce the need for data engineering in the systems.
Integrated Distribution Operations Center
Figure 3 depicts the architecture for a fully integrated distribution operations center. The integrated DMS/OMS system model is initially created using a one-time data load from the GIS. Periodic updates to the DMS/OMS model is then performed using an incremental update process from the GIS. Since the DMS and OMS use the same network model, it is only necessary to have a single update process.
As shown in Figure 3, the DMS applications and OMS applications utilize a common network model. The OMS applications are used primarily in outage response. The DMS applications typically relate to the electrical operation of the network and utilize electrical data from the integrated DMS/OMS model, such as line and cable impedances, equipment ratings, and customer load characteristics. The DMS/OMS can utilize data from other distribution IT systems that collect system data from field devices. This includes SCADA, as discussed above. SCADA continues to expand past the distribution substation and onto the feeders, providing improved situational awareness and control.
The increasing presence of AMI has many organizations asking how the AMI data can be utilized for operational purposes. Interfaces between AMI/MDM (Advanced Metering Infrastructure/Meter Data Management) and the OMS have been provided for metering pinging, outage notifications, and restoration notifications. The use of other AMI data in DMS applications, such as interval demand data and voltage violations, is being explored.
In addition, many organizations are increasing the amount of substation automation and substation computers on their systems. This provides increased access to the data in intelligent electronic devices (IEDs) that are being installed in substations and distribution system, many of which have communications capabilities. These include “more intelligent” recloser controls, switch controls, and voltage regulator controls.
The architecture of how data is transmitted between field devices and the integrated operations center will vary among distribution organizations, and there may be several approaches with a company itself. Whatever the approach, the data can assist in increasing operational awareness on the system.

Summary
Distribution organizations are increasingly turning to integrated distribution operations centers, including integrated SCADA/DMS/OMS systems and associated decision support tools, to improve their operational processes. An integrated DMS/OMS solution eliminates redundant processes for maintaining the network model and also improves operational efficiencies. Integration of SCADA and the DMS/OMS permits advanced DMS applications to access data from SCADA, analyze the real-time DMS/OMS network model, and provide increased operator efficiencies. Integration with other systems, such as AMI and substation automation systems, provide additional means to leverage the available data throughout an organization.
About the Authors
Tim Taylor is the Business Development Manager - DMS for ABB Network Management. Tim has been with ABB for almost 14 years in a number of engineering, consulting, and business development roles. Tim has performed distribution planning studies for companies around the world and has developed and taught courses on distribution planning and engineering. Tim is a Senior Member of IEEE and holds an MS in Electrical Engineering from NC State University and an MBA from UNC-Chapel Hill.
Hormoz Kazemzadeh is the Director of Marketing for ABB Network Management. He has over 18 years of experience in development, implementation, and integration of network planning and operations systems for the electric utility. Hormoz has held positions in system engineering, project management, and marketing. He holds a Masters degree in electrical engineering from the Ohio State University in Columbus, Ohio.