The document describes an analog servo drive that:
- Can provide up to 60A of peak current and 30A of continuous current from a 60-400VDC power supply.
- Includes protection against overvoltage, overcurrent, overheating and other faults.
- Can be controlled via a ±10V analog command and supports Hall, encoder and tachometer feedback.
- Has adjustable current limits, acceleration/deceleration rates, and other parameters via onboard potentiometers.
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2. Heatmap utilization for testing
3. Optimization of testing processes
4. Demo
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Execution from the test manager
Orchestrator execution result
Defect reporting
SAP heatmap example with demo
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Session Overview
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- What are the benefits of integrating InfluxDB and Grafana into the load testing stack?
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- Demonstration of InfluxDB and Grafana using a practice web application
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Neuro-symbolic is not enough, we need neuro-*semantic*Frank van Harmelen
Neuro-symbolic (NeSy) AI is on the rise. However, simply machine learning on just any symbolic structure is not sufficient to really harvest the gains of NeSy. These will only be gained when the symbolic structures have an actual semantics. I give an operational definition of semantics as “predictable inference”.
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2. Microsoft Research's GraphRAG paper and a review paper on various uses of knowledge graphs:
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- Visualization tools to display your network;
- Grid simulation tools, such as power flows, security analyses (with or without remedial actions) and sensitivity analyses;
The framework is mostly written in Java, with a Python binding so that Python developers can access PowSyBl functionalities as well.
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- Practical Applications in FME Form: Delve into key user parameter types including choice, connections, and file URLs. Allow users to control how a workflow runs, making your workflows more reusable. Learn to import values and deliver the best user experience for your workflows while enhancing accuracy.
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Sectoral targets and attacks as well as the cost of ransom
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Major cyber events in 2024
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Cyberattack types and targets
Vulnerability exploit attempts on CVEs
Attacks on counties – USA
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Cyber risk predictions
Axis of attacks – Europe
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Topics covered:
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UI automation Sample
Desktop automation flow
Pradeep Chinnala, Senior Consultant Automation Developer @WonderBotz and UiPath MVP
Deepak Rai, Automation Practice Lead, Boundaryless Group and UiPath MVP
UiPath Test Automation using UiPath Test Suite series, part 3
Advanced motion controls b60a40
1. Analog Servo Drive B60A40
Description
Power Range
Peak Current 60 A
Continuous Current 30 A
Supply Voltage 60 - 400 VDC
The B60A40 PWM servo drive is designed to drive brushless DC motors at a high switching frequency. A single red/green LED indicates operating status. The drive is fully protected against over-voltage, under voltage, over-current, over-heating and short-circuits across motor, ground and power leads. Furthermore, the drive can interface with digital controllers or be used stand-alone, and requires only a single unregulated DC power supply. Loop gain, current limit, input gain and offset can be adjusted using 14- turn potentiometers. The offset adjusting potentiometer can also be used as an on-board input signal for testing purposes.
See Part Numbering Information on last page of datasheet for additional ordering options.
Features
Four Quadrant Regenerative Operation
Adjustable Acceleration/Deceleration Rate
Adjustable Current Limits
Differential Input Command
Selectable Inhibit/Enable Logic
On-Board Test Potentiometer
Offset Adjustment Potentiometer
Selectable 120/60 Hall Commutation Phasing
Hall Velocity Mode
Encoder Velocity Mode
Differential Encoder Feedback
Directional Inhibit Inputs for Limit Switches
MODES OF OPERATION
ƒ
Current
ƒ
Duty Cycle (Open Loop)
ƒ
Hall Velocity
ƒ
Velocity
COMMAND SOURCE
ƒ
±10 V Analog
FEEDBACK SUPPORTED
ƒ
Halls
ƒ
Incremental Encoder
ƒ
Tachometer (±60 VDC)
COMPLIANCES & AGENCY APPROVALS
ƒ
UL
ƒ
cUL
ƒ
CE Class A (LVD)
ƒ
CE Class A (EMC)
ƒ
RoHS
ELECTROMATE
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2. Analog Servo Drive B60A40
BLOCK DIAGRAM
Information on Approvals and Compliances
US and Canadian safety compliance with UL 508c, the industrial standard for power conversion electronics. UL registered under file number E140173. Note that machine components compliant with UL are considered UL registered as opposed to UL listed as would be the case for commercial products.
Compliant with European CE for both the Class A EMC Directive 2004/108/EC on Electromagnetic Compatibility (specifically EN 61000-6-4:2001, EN 61000-6-2:2001, EN 61000-3-2:2000, and EN 61000-3-3:1995/A1:2001) and LVD requirements of directive 2006/95/EC (specifically EN 60204-1), a low voltage directive to protect users from electrical shock.
RoHS (Reduction of Hazardous Substances) is intended to prevent hazardous substances such as lead from being manufactured in electrical and electronic equipment.
ELECTROMATE
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3. Analog Servo Drive B60A40
SPECIFICATIONS
Power Specifications
Description
Units
Value
DC Supply Voltage Range
VDC
60 - 400
DC Bus Over Voltage Limit
VDC
425
Maximum Peak Output Current1
A
60
Maximum Continuous Output Current
A
30
Maximum Continuous Output Power
W
11400
Maximum Power Dissipation at Continuous Current
W
600
Minimum Load Inductance (Line-To-Line)2
μH
600
Low Voltage Supply Outputs
-
±10 VDC (3 mA), +5 VDC (250 mA)
Switching Frequency
kHz
15
Control Specifications
Description
Units
Value
Command Sources
-
±10 V Analog
Feedback Supported
-
Halls, Incremental Encoder, Tachometer (±60 VDC)
Commutation Methods
-
Trapezoidal
Modes of Operation
-
Current, Hall Velocity, Duty Cycle, Velocity
Motors Supported
-
Single Phase (Brushed, Voice Coil, Inductive Load), Three Phase (Brushless)
Hardware Protection
-
Invalid Commutation Feedback, Over Current, Over Temperature, Over Voltage, Short Circuit (Phase-Phase & Phase-Ground)
Primary I/O Logic Level
-
5V TTL
Mechanical Specifications
Description
Units
Value
Agency Approvals
-
CE Class A (EMC), CE Class A (LVD), cUL, RoHS, UL
Size (H x W x D)
mm (in)
234.7 x 160.2 x 88.9 (9.2 x 6.3 x 3.5)
Weight
g (oz)
2560 (90.3)
Heatsink (Base) Temperature Range3
°C (°F)
0 - 75 (32 - 167)
Storage Temperature Range
°C (°F)
-40 - 85 (-40 - 185)
Form Factor
-
Panel Mount
P1 Connector
-
26-pin, high-density, female D-sub
P2 Connector
-
15-pin, high-density, female D-sub
P3 Connector
-
5-contact, 11.10 mm spaced, tri-barrier terminal block
Notes
1.
Maximum duration of peak current is ~2 seconds. Peak RMS value must not exceed continuous current rating of the drive.
2.
Lower inductance is acceptable for bus voltages well below maximum. Use external inductance to meet requirements.
3.
Additional cooling and/or heatsink may be required to achieve rated performance. ELECTROMATE
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4. Analog Servo Drive B60A40
PIN FUNCTIONS
P1 - Signal Connector
Pin
Name
Description / Notes
I/O
1
+10V 3mA OUT
O
2
SIGNAL GND
SGND
3
-10V 3mA OUT
±10 V @ 3 mA low power supply for customer use. Short circuit protected. Reference ground common with signal ground.
O
4
+REF
I
5
-REF
Differential Reference Input (±10 V Operating Range, ±15 V Maximum Input)
I
6
VEL INPUT
Single ended reference input for external velocity signal, range ±10 V (maximum ±15 V).
I
7
ENC. VEL. MONITOR
Encoder Velocity Monitor. Analog output proportional to the frequency of encoder lines or, equivalently, to motor speed. Scaling is 25 kHz/V.
O
8
CURR MONITOR OUT
Current Monitor. Analog output signal proportional to the actual current output. Scaling is 8.9 A/V by default but may be reduced to half this value by setting DIP switch SW1-3 to OFF (see Hardware Settings section below). Measure relative to signal ground.
O
9
CURR REFERENCE
Measures the command signal to the internal current-loop. This pin has a maximum output of ±7.25 V when the drive outputs maximum peak current. Measure relative to signal ground.
O
10
AT VEL
Open Collector output specific to Hall/Encoder Velocity mode. Internally pulled up to 5V thru 10K. This output is low when the speed is within 10% of the commanded speed. Jumpers JF6 and JF7 must be set appropriately to enable this output, see jumper settings for details.
O
11
INHIBIT / ENABLE
TTL level (+5 V) inhibit/enable input. Pull to ground to inhibit drive (SW1-6 ON). Pull to ground to enable drive (SW1-6 OFF).
I
12
+INHIBIT / ENABLE
Positive Direction Inhibit (Does Not Cause A Fault Condition)
I
13
-INHIBIT / ENABLE
Negative Direction Inhibit (Does Not Cause A Fault Condition)
I
14
FAULT
TTL level (+5 V) output becomes high when power devices are disabled due to at least one of the following conditions: inhibit, invalid Hall state, output short circuit, over voltage, over temperature, power-up reset.
O
15
+5V @ 250mA
±5 V @ 250 mA low power supply for customer use. Short circuit protected. Referenced to signal ground.
O
16
SIGNAL GND
Signal Ground
SGND
17
CTLR. POWER
Controller Power. Pass-through to Port 2 (P2) for customer use.
I/O
18
CTLR. LINE 1
I/O
19
CTLR. LINE 2
User Controller Signal. Pass-through to Port 2 (P2) for customer use.
I/O
20
ENC. CH. A+
O
21
ENC. CH. A-
Differential Encoder Channel A Output. Pass-through from Port 2 (P2).
O
22
ENC. CH. B+
O
23
ENC. CH. B-
Differential Encoder Channel B Output. Pass-through from Port 2 (P2).
O
24
ENC. CH. INDEX+
O
25
ENC. CH. INDEX-
Differential Encoder Index Output. Pass-through from Port 2 (P2).
O
26
HALL VEL. MONITOR
Hall Velocity Monitor. Analog output proportional to the Hall frequency or, equivalently, to motor speed. Scaling is 100 Hz/V.
O
P2 - Feedback Connector
Pin
Name
Description / Notes
I/O
1
HALL A
I
2
HALL B
I
3
HALL C
Single-ended Hall/Commutation Sensor Inputs (+5 V logic level)
I
4
ENC. CH. A+
I
5
ENC. CH. A-
Differential Encoder Channel A Input (+5 V Logic Level)
I
6
ENC. CH. B+
I
7
ENC. CH. B-
Differential Encoder Channel B Input (+5 V Logic Level)
I
8
ENC. CH. INDEX+
I
9
ENC. CH. INDEX-
Differential Encoder Index Input (+5 V Logic Level)
I
10
CTLR. LINE 1
I/O
11
CTLR. LINE 2
User Controller Signal. Pass-through to Port 1 (P1) for customer use.
I/O
12
SIGNAL GND
Signal Ground
SGND
13
+5V @ 250mA
±5 V @ 250 mA low power supply for customer use. Short circuit protected. Referenced to signal ground.
O
14
TACH IN
Negative Tachometer Input (Maximum ±60 V). Use signal ground for positive input.
I
15
CTLR. POWER
Controller Power. Pass-through to Port 1 (P1) for customer use.
I/O
P3 - Power Connector
Pin
Name
Description / Notes
I/O
1
MOTOR A
Motor Phase A
O
2
MOTOR B
Motor Phase B
O
3
MOTOR C
Motor Phase C
O
4
POWER GND
Power Ground (Isolated From Signal Ground)
PGND
5
HIGH VOLTAGE
DC Power Input
I
ELECTROMATE
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5. Analog Servo Drive B60A40
HARDWARE SETTINGS
Switch Functions
SW1
Setting
Switch
Description
On
Off
1
Test/Offset. Switches the function of the Test/Offset pot between an on-board command input for testing or a command offset adjustment. OFF by default.
Test
Offset
2
Current loop proportional gain adjustment. ON by default.
Decrease
Increase
3
Current scaling. When OFF, increases sensitivity of current sense thus reducing both peak and continuous current limit by 50%. The scaling of the current monitor output signal becomes ½ its ordinary value when this switch is OFF.
Full-current
Half-current
4
Current ratio. Used to set continuous-to-peak current ratio. Default is ON.
Cont./Peak Ratio = 50%
Cont./Peak Ratio = 25%
5
Hall sensor phasing. Selects 120°/60° commutation phasing. ON by default.
120°
60°
6
Inhibit logic. Sets the logic level of inhibit pins.
Active Low
Active High
SW2
Setting
Switch
Description
On
Off
1
Mode selection. See mode selection table below.
-
-
2
Mode selection. See mode selection table below.
-
-
3
Mode selection. See mode selection table below.
-
-
4
Velocity feedback polarity. Changes the polarity of the internal feedback signal and the velocity monitor output signal. Inversion of the feedback polarity may be required to prevent a motor run- away condition.
Standard
Inverted
5
Outer loop integration. Activates or deactivates integration. OFF, by default, for current mode and ON for other modes.
Active
Inactive
6
Outer loop integral gain adjustment. It is recommended to leave this switch OFF for most applications, but ON for Hall Velocity Mode.
Decrease
Increase
Mode Selection Table
Mode
SW2-1
SW2-2
SW2-3
SW2-5
Encoder
Tachometer
CURRENT
OFF
OFF
OFF
OFF
Not Connected
Not Connected
DUTY CYCLE
OFF
OFF
ON
ON
Not Connected
Not Connected
HALL VELOCITY*
OFF
ON
OFF
ON
Not Connected
Not Connected
ENCODER VELOCITY*
ON
OFF
OFF
ON
Connected
Not Connected
TACHOMETER VELOCITY
OFF
OFF
OFF
ON
Not Connected
Connected
EXTERNAL VELOCITY
OFF
OFF
OFF
ON
Not Connected
Not Connected
*NOTE: See details of switch SW2-4 for further Hall/Encoder Velocity configuration information.
Potentiometer Functions
Potentiometer
Description
Turning CW
1
Loop gain adjustment for duty cycle / velocity modes. Turn this pot fully CCW in current mode.
Increases gain
2
Current limit. It adjusts both continuous and peak current limit while maintaining the continuous/peak ratio set by the dipswitches.
Increases limit
3
Reference gain. Adjusts the ratio between input signal and output variables (voltage, current, or velocity).
Increases gain
4
Offset / Test. Used to adjust any imbalance in the input signal or in the amplifier. Can also be used as an on-board signal source for testing purposes.
Adjusts offset in negative direction
Note: Potentiometers are approximately linear and have 12 active turns with 1 inactive turn on each end.
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6. Analog Servo Drive B60A40
Through-hole Components†
Location
Description
CF3*
Velocity Loop Integrator. Through-hole capacitor that can be added for more precise velocity loop tuning. See section below on Tuning with Through-hole components for more details.
CF4*
Current Loop Integrator. Through-hole capacitor that can be added for more precise current loop tuning. See section below on Tuning with Through-hole components for more details.
RF1*
Tachometer Input Scaling. Through-hole resistor that can be added to change the gain of the tachometer input. See section below on Tachometer Gain for more details.
RF2*
Through-hole resistor that can be added to change the gain of the external velocity input. See section below on External Velocity Gain for more details.
RF3
First of two resistors used to set the acceleration rate.
RF4
Second of two resistors used to set the acceleration rate.
RF5
Second of two resistors used to set the deceleration rate.
RF6
First of two resistors used to set the deceleration rate.
RF7*
Current Loop Proportional Gain. Through-hole resistor that can be added for more precise current loop tuning. See section below on Tuning with Through-hole components for more details.
Tachometer Gain
Some applications may require an increase in the gain of the tachometer input signal. This occurrence will be most common in designs where the tachometer input has a low voltage to RPM scaling ratio. The drive offers a through-hole location listed in the above table where a resistor can be added to increase the tachometer gain. Use the drive’s block diagram to determine an appropriate resistor value.
External Velocity Gain
Some applications may require an increase in the gain of the external velocity input signal. The drive offers a through-hole location listed in the above table where a resistor can be added to increase the external velocity gain. Use the drive’s block diagram to determine an appropriate resistor value.
Acceleration/Deceleration Setting Details
The acceleration and deceleration rates can be set independently using through-hole resistors at locations RF3, RF4, RF5, and RF6 (see table below). The rates are based on + or – 10 Volts to the Reference inputs. The “Time” listed in the table below is the time it takes to reach the 10-Volt input. The ramping rates are linear with respect to time. For example, if the input were only 5 Volts, the time to ramp to this voltage would be half the time to ramp to 10 Volts. These locations are silk-screened on the PCB for easy identification.
Acceleration
Deceleration
Time (s)
RF3 (kΩ)
RF4 (kΩ)
RF5 (kΩ)
RF6(kΩ)
1
50
50
50
50
2
50
20
50
20
3*
10
10
10
10
4
500
20
500
20
5
50
5
50
5
6
500
10
500
10
7
50
2
50
2
8
50
1
50
1
9
20
0.1
20
0.1
10
100
0.1
100
0.1
* Default setting
Tuning With Through-hole Components
In general, the drive will not need to be further tuned with through-hole components. However, for applications requiring more precise tuning than what is offered by the potentiometers and dipswitches, the drive can be manually modified with through-hole resistors and capacitors as denoted in the above table. By default, the through-hole locations are not populated when the drive is shipped. Before attempting to add through-hole components to the board, consult the section on loop tuning in the installation notes on the manufacturer’s website. Some general rules of thumb to follow when adding through-hole components are:
•
A larger resistor value will increase the proportional gain, and therefore create a faster response time.
•
A larger capacitor value will increase the integration time, and therefore create a slower response time.
Proper tuning using the through-hole components will require careful observation of the loop response on a digital oscilloscope to find the optimal through-hole component values for the specific application.
†Note: Damage done to the drive while performing these modifications will void the warranty.
ELECTROMATE
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7. Analog Servo Drive B60A40
Jumper Settings
Jumper
Description
Configuration
SMT Jumper (0Ω Resistor)
Not Installed
Installed
JF6
First of two jumpers used to configure the AT VEL output (P1-10). Both jumpers must be set appropriately.
Hall Velocity
Encoder Velocity
JF7
Second of two jumpers used to configure the AT VEL output (P1-10). Both jumpers must be set appropriately.
Encoder Velocity
Hall Velocity
JF8
First of two jumpers used to enable adjustable accel/decel rate control. Both jumpers must be set appropriately. The default setting is installed (accel/decel disabled).
Enabled
Disabled
JF9
Second of two jumpers used to enable adjustable accel/decel rate control. Both jumpers must be set appropriately. The default setting is not installed (accel/decel disabled).
Disabled
Enabled
ELECTROMATE
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Toll Free Fax (877) SERV099
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sales@electromate.com
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8. Analog Servo Drive B60A40
MECHANICAL INFORMATION
P1 - Signal Connector
Connector Information
26-pin, high-density, female D-sub
Details
TYCO: Plug P/N 1658671-1; Housing P/N 5748677-2; Terminals P/N 1658670-2 (loose) or 1658670-1 (strip)
Mating Connector
Included with Drive
No
P2 - Feedback Connector
Connector Information
15-pin, high-density, female D-sub
Details
TYCO: Plug P/N 748364-1; Housing P/N 5748677-1; Terminals P/N 1658670-2 (loose) or 1658670-1 (strip)
Mating Connector
Included with Drive
No
P3 - Power Connector
Connector Information
5-contact, 11.10 mm spaced, tri-barrier terminal block
Details
Not applicable
Mating Connector
Included with Drive
Not applicable ELECTROMATE
Toll Free Phone (877) SERVO98
Toll Free Fax (877) SERV099
www.electromate.com
sales@electromate.com
Sold & Serviced By:
10. Analog Servo Drive B60A40
PART NUMBERING INFORMATION
APeak VoltagePeak Current40- Additional Options* B or BX:Brushless drive. Maximum peak current rating in Amps. Peak voltage rating scaled 1:10 in Volts. Power Supply:DC Power SupplyDrive TypeBE:Encoder Velocity Mode AvailableBD:PWM CommandBDC:PWM Command, Closed Current LoopS or SX:Commutated Sine CommandRevisionAssigned a letter (A through Z) by manufacturer. AC:AC Power SupplyFAC:AC Power Connecter Relocated to the FrontI:Optical IsolationIsolation Option60B-ANP:Analog Position Loop*Options available for orders with sufficient volume. Contact ADVANCED Motion Controls for more information.
ADVANCED Motion Controls analog series of servo drives are available in many configurations. Note that not all possible part number combinations are offered as standard drives. All models listed in the selection tables of the website are readily available, standard product offerings.
ADVANCED Motion Controls also has the capability to promptly develop and deliver specified products for OEMs with volume requests. Our Applications and Engineering Departments will work closely with your design team through all stages of development in order to provide the best servo drive solution for your system. Equipped with on-site manufacturing for quick- turn customs capabilities, ADVANCED Motion Controls utilizes our years of engineering and manufacturing expertise to decrease your costs and time-to-market while increasing system quality and reliability.
Examples of Modifications and Customized Products
Integration of Drive into Motor Housing
Integrate OEM Circuitry onto Drive PCB
Mount OEM PCB onto Drive Without Cables
Custom Control Loop Tuned to Motor Characteristics
Multi-axis Configuration for Compact System
Custom I/O Interface for System Compatibility
Custom PCB and Baseplate for Optimized Footprint
Preset Switches and Pots to Reduce User Setup
RTV/Epoxy Components for High Vibration
Optimized Switching Frequency
OEM Specified Connectors for Instant Compatibility
Ramped Velocity Command for Smooth Acceleration
OEM Specified Silkscreen for Custom Appearance
Remove Unused Features to Reduce OEM Cost
Increased Thermal Limits for High Temp. Operation
Application Specific Current and Voltage Limits
Feel free to contact Applications Engineering for further information and details.
Available Accessories
ADVANCED Motion Controls offers a variety of accessories designed to facilitate drive integration into a servo system.
Visit www.a-m-c.com to see which accessories will assist with your application design and implementation.
Power Supplies
Filter Cards
Shunt Regulators
Drive(s)
To Motor
All specifications in this document are subject to change without written notice. Actual product may differ from pictures provided in this document.
ELECTROMATE
Toll Free Phone (877) SERVO98
Toll Free Fax (877) SERV099
www.electromate.com
sales@electromate.com
Sold & Serviced By: