UC-USB module with 16 optocoupler inputs

Name: UC-USB module with 16 optocoupler inputs - DEDITEC
SKU: UC-USB-O16
Price: 298.00 EUR
Availability: InStock

The UC-USB-O16 USB module offers 16 digital inputs (DI) with optocoupler technology for safe, electrically isolated signal acquisition in industrial environments. Voltage ranges from ±5 V to ±50 V are reliably detected. With integrated 16-bit counters and adjustable filters, the PLC module is ideal for detecting limit switches or evaluating fast pulses in machines and test benches. Plug-and-play via USB enables quick integration.

€ 354,62 Incl. 19% VAT plus shipping

SKU: UC-USB-O16 Categories: UC series, UC-USB

Our promise to you

Product Description – USB digital input module with optocouplers for PLC

The UC-USB-O16 with 16 digital inputs (DI) from DEDITEC is a high-performance, industrial-grade PLC module designed specifically for precise signal acquisition and reliable automation tasks. The inputs are designed as optocoupler inputs and provide safe galvanic isolation between field signals and internal electronics. This effectively protects the module from interference, voltage spikes, and ground loops—a crucial advantage in industrial environments.

The 16 digital inputs support voltage ranges from ±5 V to ±50 V AC/DC, making them flexible for use with a wide variety of sensor and switching signals. Each channel features a 16-bit counter (up to 10 kHz) as well as flip-flop functions, ensuring that even fast pulses or short signal changes are reliably detected. An adjustable input filter (1–255 ms) suppresses noise pulses and ensures stable signal evaluation.

Thanks to its USB-C interface and plug-and-play functionality, the USB digital input module with optocouplers for PLC is automatically detected and is ready for immediate use without any complex configuration. The integrated status LEDs for each channel significantly simplify diagnostics and commissioning. The DELIB API is available to developers on Windows and Linux, including support for C, C++, C#, Java, and other languages.

Typical applications include the detection of limit switches, the monitoring of sensors, pulse counting on machines, integration into test benches, and use as a robust PLC module in laboratory and industrial environments. The UC-USB-O16 thus offers a reliable, flexible, and modern solution for all tasks requiring digital inputs, optocoupler technology, and USB connectivity.

Reliable USB communication interface for precise system integration

The USB interface of the UC-USB-O16 is based on a modern USB-C connection and enables reliable and fast communication with the host system. It supports USB 2.0 as well as USB 1.1 and achieves a data transfer rate of up to 480 Mbit/s. Thanks to plug-and-play functionality, the USB digital input module with optocouplers for PLC is automatically recognized by the operating system and is immediately ready for use without additional basic configuration. Communication is handled via an optimized connection to the DELIB driver library, ensuring efficient and low-latency control. Typical access times in the millisecond range enable precise and stable data transmission even in time-critical applications. The USB-C interface also provides a robust and future-proof physical connection.

USB control via API commands and integrated driver interface

The USB connection of the module enables direct and straightforward control via an integrated driver and API structure (DELIB API). Following the plug-and-play principle, the USB digital input module with optocouplers for PLC is automatically detected by the system and can then be addressed in software through standardized function calls. For all digital inputs and outputs as well as counter and status functions, defined API commands are available to read and control states.
Communication with the UC-USB-O16 is typically handled via a DLL-based library that can be integrated into common programming languages such as C, C++, C#, Java, VB, and LabVIEW. This allows the development of custom applications, control programs, or test environments without the need to handle low-level USB communication.
In addition, the module provides a command-line interface (CLI), enabling simple control and query commands to be executed directly from scripts or terminal applications.
In practical use, this means that switching states of individual outputs or reading input signals can be controlled in real time using just a few API function calls. As a result, USB control is particularly well suited for automation tasks, test benches, and PC-based control applications with direct hardware integration.

Galvanically isolated digital inputs with filtering functions for reliable signal acquisition

The digital inputs on the USB digital input module with optocouplers for PLC are implemented as opto-isolated switching inputs, ensuring reliable galvanic isolation between the field side and the internal electronics. They are designed for industrial 24 V AC/DC signals and enable safe detection of switching states even in electrically noisy environments. The integrated filtering function suppresses short interference pulses, ensuring stable signal processing.
In addition, the inputs feature event detection that reliably captures signal transitions and makes them available for further processing. In combination with counter and flip-flop functions, even fast pulses or state changes can be evaluated precisely. Each input of the UC-USB-O16 is also equipped with an individual status LED that visually indicates the current switching state directly on the device, enabling fast on-site diagnostics.
As a result, the digital inputs are ideally suited for industrial automation tasks where robust and reliable signal acquisition is required.

Event Control – event-based automation

The Event Control function enables direct, event-driven processing of both digital and analog signals in the USB digital input module with optocouplers for PLC, without requiring cyclic polling by higher-level software. Digital signal transitions can immediately trigger internal actions, while analog signals can generate events based on defined thresholds, measurement ranges, or significant value changes. This allows responses to be implemented much faster and more resource-efficiently compared to traditional polling-based processing.
The event logic can be flexibly configured, enabling both simple switching conditions and more complex dependencies between digital and analog signals. In addition, functions such as filtering, hysteresis, and threshold monitoring are available to ensure stable and reliable trigger conditions.
As a result, Event Control is particularly well suited for automation applications where signals must be evaluated intelligently and processed immediately.

Robust industrial design with a well-engineered connection and mounting architecture

The USB digital input module with optocouplers for PLC is housed in a compact DIN rail enclosure specifically designed for control cabinet use, enabling space-saving integration into industrial systems. With a housing width of 22.5 mm, it supports high packing density while still ensuring good accessibility to all connections. For electrical wiring of the UC-USB-O16, a pluggable WAGO spring-clamp system is used, enabling tool-free and vibration-resistant installation and supporting conductor cross-sections of up to 1.5 mm². In addition, a separate 5-pin connector is provided for the power supply, ensuring a clear separation between signal and operating voltage. The entire connection architecture is designed for misconnection protection and fast maintainability, offering clear advantages during service and commissioning processes. Overall, the design combines a robust mechanical structure with a practical, modular wiring concept for continuous industrial operation.

Maintenance and Long-Term Planning

The UC-USB-O16 supports users with a durable, industrial-grade architecture that enables predictable use over many years. The combination of robust drivers, comprehensive documentation, and the ICT diagnostic tool simplifies commissioning and maintenance. Electrical isolation and high-quality electronics ensure reliable operation, while support and continuous updates guarantee seamless integration into professional automation environments.

Technical Specifications

The UC-USB-O16 is a USB module with 16 digital inputs that are safely electrically isolated via optocouplers. It handles input voltages ranging from ±5 V to ±50 V AC/DC and features 16-bit counters, filter functions, and LED status indicators for precise signal acquisition. Typical applications include the detection of limit switches and the evaluation of fast pulses.

USB interface:

USB 2.0 interface up to 480 Mbit/s
Quick setup thanks to plug-and-play integration
Control: API for Windows and Linux (DELIB driver library), command-line interface

Digital inputs:

Type: AC/DC optocoupler
Signal level: ±5 V to ±15 V or ±15 V to ±30 V
16-bit counter per channel (up to 100 Hz)
Detects a transition from low to high and from high to low (flip-flop)
Status LED for each channel

Additional features:

Configurable event control
M2M functionality

General
Technical data
ICT-Tool
Configuration
Event-Control
DELIB-API commands
Connection examples
Connectors
Downloads & manuals
Scope of delivery
Accessories

Digital inputs

Digital signal states can be recorded with our optocoupler inputs. Input and output circuits are electrically isolated from each other up to 2.5 kV.

Digital-in input filter

With our digital-in modules, an input filter can be set in a time interval of 1 ms...255 ms for filtering interference pulses.

Counter

Each input has a 16-bit counter.

Detection of state changes

Status changes that occur between readout cycles are reliably recorded by internal status change flip-flops and can be read out separately via software. In addition, such an event is signaled by a status LED.

USB interface with Plug & Play

Thanks to Plug & Play, our modules with USB interface are automatically recognized and are immediately ready for use without any configuration. Configuration is only required if several USB modules from the same product series are used on the same system.

Plug connector

A screwless system from the manufacturer WAGO® Kontakttechnik is used as the connector. The 1-wire female connectors are 100 % protected against mismating and have an ejection and locking mechanism.

Easy installation thanks to DIN rail bus

Thanks to the practical bus connector, which is clipped into the DIN rail, individual modules of a system can be added or replaced very easily. This Plug'n Play principle makes commissioning easier for you and eliminates the need for tedious wiring.

LEDs

Each digital input and output has a separate LED that lights up when the signal status is active. The status of the operating voltage, communication with the interface, error events or the occurrence of a timeout can also be displayed.

Software and control for programmers

Our supplied DELIB driver library makes it easy to address the product via our API in almost all programming languages under Windows and Linux.

We offer support for the following programming languages:

C
C++
C#
VB
VBA
VB.Net
Java

Symbol für unterstützte Programmiersprachen

Command-Line-Interface

With the help of the command line interface, or CLI for short, our products with Ethernet or USB interface can be easily addressed via the command line. Our digital and analog inputs/outputs are supported. The CLI is available for Windows and Linux operating systems.

Power supply	+12 V ... +24 V DC
LEDs general	Interface communication Module status One LED per input and output channel (only for digital modules)
LEDs product-specific	A/D-version: A/D channel active / not active Read/write access to A/D channel U mode active / not active I mode active / not active D/A-version: D/A channel active / not active Read/write access to D/A channel U mode active / not active Thermo version: A/D channel active / not active Read/write access to A/D channel U mode active / not active I mode active / not active
DIN rail mounting	35 x 7,5 mm
Operating temperature	+10 °C ... +50 °C
Dimensions	120 mm x 22.5 mm x 111 mm (H x W x D)

Special features

Event-Control	With our event control, you have the option of linking occurring events to a specific action. With the help of our ICT tool, the control tasks can be stored directly in the module memory thanks to an intuitive “if-then” logic. Monitor, control and regulate without an additional control PC.

Interfaces

USB Interface

USB-interface	Connection: Type C USB 2.0 / USB 1.1 interface with up to 480 Mbit/s
Access speed	USB: 2,06 ms Calculated with 1000 accesses to the module via the DELIB driver library with the command DapiDoSet32

Inputs/Outputs

Digital inputs (optocoupler)

Optocoupler	Type: AC / DC +-15 V ... +-30 V AC / DC signal voltage (optional +-5 V ... +-15 V AC / DC) Galvanic isolation between input and output circuit: up to 2.5 kV AC for 1 minute Maximum input current: 14 mA
Input filter	Default value: 0 ms Value range: 0 (off), 1 (ms) ... 255 (ms)
Input counter	16-bit counter per channel Maximum possible counts: 65535 per channel. Reset to zero after memory overflow Internal counting logic up to 10 kHz Programmable filter for input channels (flip-flop and counter) Minimum low or high pulse duration: 5 ms ... 255 ms
Flip-flops	Detects a change from low to high and high to low level Detects the input status change between two readout processes Input status flag is reset during readout

Connectors

Plug connector 16-pin	Type: Wago contact technology 713-1108/037-000 Pluggable female connector with locking mechanism 100 % protected against mismating 1-wire connection for all conductor types up to 1.5 mm²

Plug connector 5-pin	Type: Phoenix Contact 1876343 Pluggable screw terminal 100 % mismating protected For all conductor types from 0.14 mm² to 1.5 mm²

The ICT-Tool

Integration, configuration and testing - Our all-in-one Windows tool contains all the functions you need to put our products into operation quickly, easily and efficiently. Start with the setup and configuration, install firmware updates and use the extensive test and diagnostic options. The integrated help menu provides additional support if required.

General

Info

Configuration

Machine-to-Machine

Event-Control

I/O-Tests

Diagnosis

Firmware-Update

Settings

Below you will find a brief overview of the program’s basic menus.

Module selection
Here you can integrate a new product into the ICT tool by clicking on the “+” symbol and then configure it.

ICT TreeView
In the TreeView, on the left-hand side of the program window, you can see the respective control elements or functions that are supported by your selected module. The scope of the functions depends on the respective product.

Overview
All relevant module information can be accessed here at a glance.

Module name
Module ID
Firmware revision
MAC address
LAN and WiFi Network address (module dependent)

Inputs / Outputs
This overview shows the number of I/Os supported by your module.

Module infos
Here you will find all the important feature information for your module.

General features
Here you will find all the important feature information for your module.

Digital I/O features
Here you will find information about the digital I/Os supported by the module.

Analog I/O features

Here you will find information about the type of analog I/Os supported by your module.

Special I/O features

Here you will find information about the type of special I/Os supported by your module.

In den folgenden Kapitel, würden wir Ihnen unsere neue All-In-One-Software gerne genauer vorstellen.

Info
All relevant module information can be called up here at a glance.

Module name
Module ID
Firmware revision
Interface type
Current DIP switch setting (only for Ethernet modules)

Identification
If several DEDITEC Ethernet modules are active in the network, a signal LED on the selected module can be activated via an identification function. This facilitates visual assignment.

Restart
You can restart your module here. The module status shows whether the restart was successful.

USB configuration
If you want to use several USB modules from the same product series on one PC, each of these modules must first be assigned its own module number.

LAN info
On this information page, you will find the current LAN network information and all the settings for your module at a glance.

LAN configuration
Integrate the product into your network or control it directly via a 1-to-1 connection.
The following parameters can be changed.

Board name
DHCP on/off
IP address
Subnet mask
Default gateway
TCP Port

WiFi info
All important WiFi settings are displayed on this page

WiFi configuration
Here you can change the network settings of the selected WiFi product.

The following settings can be made:

Board name
WLAN on/off
Router name
Router password

WPS
With the WPS function, your module can be connected to the router quickly and easily, automatically (WPS on the router is required)

CAN configuration
With our CAN products in the BS, NET and UC series, settings for the interface and the TX/RX packets can be made using the ICT tool.

More information can be found here:

Serial configuration
For our serial products in the BS, NET, UC and RO series, changes to the interface can be made using the
ICT tool.

More information can be found here:

Modbus TCP
Here you can set the Modbus TCP configuration of the module.

The following configurations can be made.

Enable/disable access via Modbus TCP
TCP port

TCP encryption
Here you can make settings for the encryption of your module.

The following configurations can be made.

Allow unencrypted protocol
Allow “User” encryption mode
User password
Allow “Admin” encryption mode
Admin password

NTP configuration
You can make changes to the NTP service here.

The following configurations can be made.

NTP service on/off
server
Port
Timezone

WEB-Login
Here you can change the login settings of the web interface.

The following configurations can be made.

Session duration
Login name
Login password
Allow I/O access via web interface

D/A Default Values
Here you can set the D/A values and modes with which the module should be started.
The value and mode can be set individually for each channel.

Watchdog configuration
Here you can make and save settings on your watchdog stick.

Save or Load config
Using the “Save or Load config” function, you can save your entire module configuration in an external XML file.
This means you can always load your module in the desired original state.

The following configurations can be saved depending on the module type.

USB configuration
LAN configuration
WiFi configuration
TCP encryption
NTP configuration
Serial configuration
CAN configuration

Status
This gives you an overview of the activity of the transmitter and receiver module

The following information from the transmitter module is displayed:

Status of the activity: If the check mark is set, this action is currently being performed.
Total number of actions performed. Is reset to 0 after a restart of the module.
Number of actions per second.
Number of DELIB errors that occur when executing commands from the DEDITEC driver library.

The following information from the receiver module is displayed:

Connected: If the check mark is set, the transmitter and receiver modules are connected.
IP address of the receiver module.
Number of connection attempts.

Receiver modules
You can set the network settings of the receiver module here.

The following settings can be made

Name for the receiver module
Network settings of the receiver module
Timeout
Encryption type/ password

Action
With an action, you define which input signal is to be sent from the transmitter module to which output of a receiver module.

The following settings can be made:

Type of task (digital, analog)
Which receiver module should be used
The interval at which the operations are to be carried out
Start channel of the transmitter module
Number of channels to be transmitted
Start channel of the receive module

In the image on the right, DI data is sent every 100ms from channel 3(CH Start) to channel 8 ((CH Start) + (CH Count)) to channels 0-5 of the target module.

In den folgenden Kapitel, würden wir Ihnen unsere neue All-In-One-Software gerne genauer vorstellen.

Status
The Status area provides an overview of all active events and executed actions.

The following information is listed:

Event number
Event type
Time interval of the event
Number of events that have occurred
Action number
Number of triggered actions
Number of other actions

Events configuration
Up to 16 different events can be created in the configuration menu. An event can be used, for example, to define switching thresholds at the analog inputs or logical states at the digital inputs of the module and link them to an executable action. The configuration itself is saved permanently in the module configuration memory of the module.

The following event modes are available, depending on the module type:

DI: High-Low state of a digital input.
DI flip-flop: Status change of a digital input (is stored in the module with the so-called flip-flop flag and deleted again after readout).
DO readback: ON-OFF status of a digital output (is read out using a DO readback command).
A/D: Current or voltage level at the analog inputs

Configuration actions
Up to 16 different actions can be created in the configuration menu. An action defines what should happen within an event after a condition is met.

The following action modes are available, depending on the module type:

Set DO output: Switches a digital output on or off
Set D/A output: Outputs a current or voltage value at an analog output
Send CAN packet: A special CAN TX event is triggered (up to eight CAN TX events can be configured separately).

Digital Out
Hier können Sie die digitalen Ausgänge Ihres Modules ein- und ausschalten.

Folgende Funktionen können in dieser Form getestet werden.

Kanalweise Ein- und Ausschalten der digitalen Ausgänge
Readback der Kanäle
Setzen eines Digitalausgangs für eine bestimmte Zeit (Modulabhängig)
Gibt an welchen Status die Kanäle nach Ablauf der Zeit einnehmen sollen (Modulabhängig)
Testen der Ausgänge

Digital Out
All digital outputs of your product can be checked by clicking on the buttons.

The following switching options are possible:

Switching on and off channel by channel
Channel-by-channel switching on or off for a specific time (product-dependent)
Reading back the switching status (readback)

Digital In
In this view, the logical states of all optocoupler inputs can be read out.

The following information is displayed:

Logical status of the inputs (ON/OFF)
Number of detected pulses (counter function)
Change of state detected (flip-flop)

TTL I/O
In this menu, the TTL channels of the module can be configured as inputs or outputs. The individual TTL outputs can be switched on or off by pressing the buttons. In addition, the status of all TTL inputs can be read out.

The tool offers the following functions:

Configuration of the channels as input or output (in blocks of 8)
Switching on and off channel by channel
Reading back the switching status (output readback)
Displaying the logical status of the inputs (input readback)

Analog Out
Here you can test the analog outputs of the module and manually enter any voltage or current value.

Analog In
In this menu, voltage or current values of all A/D channels can be displayed.
It is also possible to activate our A/D software filter with different filter levels.

CAN Runtime Parameter

Here you can change the CAN settings of the interface, the RX and TX packets in runtime.

The following settings can be made:

Baud rate
Extended ID
Active on/off
CAN ID
Mode

CNT48

Here you can read out the counter readings of a counter module, select filter options and set various counting modes.

The following counting modes are supported:

Read on rising edge
Read on rising edge x2
Read on rising edge x4
Period duration
Frequency measurement
PWM measurement

Pulse generator
The pulse generator can be used to generate square-wave signals. High and low time as well as the number of pulses can be set here.

PWM Out
In this menu you have the option of testing various PWM frequencies. In addition, the duty cycle can be entered manually for each individual channel.

Temp
The temperature of all connected temperature sensors is displayed here directly in °C.

Graphical display
This menu allows a graphical representation of all analog input signals, such as A/D, temperature or FIFO-IN.

Watchdog
This tool can be used to check the configured watchdog parameters for correct function.

I/O – Timeout

You can use the timeout function in the I/O area to simulate a timeout case for your module.

The following is a description of the timeout window

Read / Write symbol: Flashes to indicate an active connection to the module
Automatic access: Removing the tick triggers a timeout after the timeout time has expired
Manual access: Manual retrieval of data from the module
Timeout status: Shows whether the timeout is active and whether a timeout event has occurred
Timeout mode: Selection between 3 timeout modes, Normal, Reactivate and Secure
Timeout duration: The time after which the timeout should be triggered is set here
Activate / deactivate: Activates or deactivates the timeout function

Access times tests
You can test the access times for the module here. The following access time tests can be performed:

Register – Read/Write/Write + Readback
Digital I/O – Read/Write/Write + Readback
Analog I/O – Read/Write/Write + Readback

Access times tests

This test can be used to determine the access times to the module. The test values are read and written in 8, 16, 32, or 64-bit commands.

Access times Register
The following example checks the register accesses to an Ethernet module. The average access time here is 0.5 ms.

Access times Analog I/O
In the following example, the access times to an Ethernet module with analog I/Os are checked. The average access time here is 0.6 ms.

Access times Digital I/O
In the following example, the access times to an Ethernet module with digital I/Os are checked. The average access time here is 0.6 ms.

Cable feedback tests
For this test, the digital or analog outputs of the module are connected to the corresponding digital or analog inputs of the module via cable. The feedback test now checks whether the output and input values match.

Cable return test

The cable return test can be used to check the function of all digital and analog inputs and outputs (I/Os) of a module. To do this, inputs and outputs are wired together externally on a 1:1 basis. The test software analyzes whether the output signals arrive correctly at the inputs, thereby identifying wiring errors or hardware defects.

Analog test
In analog test mode, the D/A converter outputs defined test voltages, which are then read in by the A/D converter and compared with the target values. The software counts the number of test runs and automatically documents any deviations.

Digital test
In the digital test, the switching states of the relay or MOSFET outputs are fed back externally to the optocoupler inputs. Here, too, the software counts and compares the number of cycles and automatically detects transmission errors or deviations.

Cable return test

A/D ripple
The ripple test displays the residual ripple of the individual A/D inputs.

A/D quality measurements

The quality of an A/D measurement is influenced by various factors and can be affected by external interference. A reliable method for checking measurement quality is to measure a stable battery voltage. Our diagnostic tools can be used to determine the residual ripple and noise behavior.

A/D ripple
The A/D ripple test can be used to measure the residual ripple of the individual A/D inputs and check for interference signals such as mains hum or voltage instabilities.

A/D noise
The noise behavior of each A/D channel can be displayed graphically using A/D noise measurement. Additional filter stages with averaging can be used to smooth and improve the measurement signal.

FIFO In/Out

The software FIFO test can be used to specifically test the integrated FIFO buffering of our digital and analog NET I/O modules. Depending on whether it is an input or output module, data is read from the submodule FIFO or written to the submodule FIFO.

FIFO settings

The submodule number can be used to specify which module is to be tested. The start and end channels can also be used to transmit several channels simultaneously. In addition, the transmission frequency can be set and the desired FIFO mode selected – for example, for the use of test values or the actual measured values of the module.

All important information at a glance

During program execution, key information such as the size of the data packets, free and occupied bytes in the FIFO buffer, the number of data packets sent or received, and the current FIFO status are clearly displayed.

D/A output test

The D/A output test enables targeted testing of each individual D/A channel of a module. A freely selectable test voltage can be output directly. Currently, simple square wave signals with configurable high and low times are available. The signals can be monitored simultaneously with an oscilloscope. This function is also ideal for long-term tests. The test software detects DELIB errors and logs them automatically.

Mustertext

DO 4* value + wait

In this test, adjustable 16-bit values are written to the digital outputs of the module.
The values are sent to the module using the DapiDOSet16 command. The start channel is always channel 0.
You can set different wait times between the individual calls.
The test is intended for testing the functionality of the module.

Mustertext

Modbus I/O test

In the diagnostics section of the ICT-Tool, you can test the module’s digital and analog inputs and outputs directly via Modbus TCP. Register addresses as well as transfer and return values are displayed in a debug panel, allowing you to quickly diagnose problems with the D/A converter, for example. A complete overview of all register addresses and examples can be found in the Modbus manual at the following link:

To benefit from the latest functions and prevent errors, we recommend that you always keep your DEDITEC product up to date.

Flash Files
Downloading the firmware flash file package via the ICT tool

Go to Flash Files in the “Firmware update” menu
Click on the download button to start the download.
Administration rights are required for the automatic unpacking of the flash files. If these rights are not available, the files are downloaded to the download area of your PC and must be extracted manually to the installation directory.
\DEDITEC\DELIB\programs\flash_files

Downloading the firmware flash file package via the DEDITEC homepage

Download the required firmware flash file package from our homepage: Downloads -> Software -> Firmware
Extract the files to the following installation path: ..\DEDITEC\DELIB\programs\flash_files

Flash modules
In the “Firmware update” menu, select the module you want to update and then click on the “Flash modules” or “Flash submodules” button.
The firmware is now updated and the module is then restarted automatically.

Information on the firmware flasher
The following information is displayed in the firmware flasher:

Last FW: Displays the last firmware version
Current FW: Displays the currently installed firmware version
Newest FW: Displays the latest firmware version
Log: Displays status or error messages during the flash process

In den folgenden Kapitel, würden wir Ihnen unsere neue All-In-One-Software gerne genauer vorstellen.

General
Here you can make general configurations to the ICT tool.

The following changes can be made:

Language – setting between German and English possible

Updates
Here you can search for available DELIB or firmware updates.

Automatic update search at program start
Search for DELIB updates
Search for firmware updates

Error log
Here you can make settings for the deditec_debug.log. This is saved under the path C:\Users\?USER?\AppData\Local\DEDITEC.

The following settings can be made:

Enable writing to the debug.log
Activate log notifications
Activate automatic deletion of the debug.log
Setting after how many days the debug.log should be deleted
Set the maximum size of the debug.log

DELIB – DebugView – Global

Settings can be made here for the information that is to be displayed with the DebugView.

Activate debug output
Activate display of errors

DELIB – DebugView – Details
More detailed settings can be made here for the information to be displayed with the DebugView.

Configuration our USB modules

Thanks to plug & play, our USB modules are automatically recognized and are immediately ready for use without any configuration. Configuration is only required if several USB modules from the same product series are used on the same system.

Using multiple USB modules on one PC

If you want to use more than one USB module of the same type on a computer, each module must first be assigned its own module number. The module number is assigned in the configuration menu of our ICT tool.

General information on Event-Control

General

Description

Statistics

Events

Actions

In den folgenden Kapitel, würden wir Ihnen unsere neue All-In-One-Software gerne genauer vorstellen.

To make our modules even more customer-friendly and flexible and to make it easier for you to enter the world of automated control technology, we have implemented Event-Control as a new feature in our products. This function can be used to implement small control tasks that are stored in the module. These control tasks are configured as events and actions and then executed automatically according to the “if-then” principle.

Configuration in the ICT-Tool
The ICT-Tool can be used to configure and monitor 16 events and 16 actions.

Processing in the module
The events stored in the module are automatically monitored and processed by the CPU in the module after the module is started. As soon as the set condition (“event”) is fulfilled, the corresponding action is executed. This automatism in the module makes an additional control PC with associated user software superfluous.

Functions
The following actions, among others, can be combined with the Event-Control:

Monitoring the analog and digital inputs (A/D, DI)
Setting switching thresholds for analog inputs
Switching the module outputs (relay, MOSFET, D/A)
Sending CAN packages

We are constantly expanding the range of promotional options. We are also happy to implement your special customer requirements on request.

Modulauswahl
Hier können Sie Ihre Module mit einem Klick auf das „+“ Symbol ins ICT-Tool einbinden, um diese anschließend konfigurieren oder testen zu können.

Module series that support this function:

BS-USB2 series
BS-WEU series
NET series
UC series
CAN-Box series

Module series that do not support this function:

Starter series
RO series
COS series

ICT Treeview
Im Treeview auf der linken Seite des Programmfensters, sehen Sie die jeweiligen Formen, die von Ihrem Modul unterstützt werden.
Mit einem Klick können Sie sich diese Form dann im rechten Teil des Programmes anzeigen lassen und mögliche Konfigurationen oder Tests durchführen.

In den folgenden Kapitel, würden wir Ihnen unsere neue All-In-One-Software gerne genauer vorstellen.

With the Event-Control module, you can react flexibly and automatically to external signals – directly on the I/O module, without a PC or additional controller.

How does it work?
The system registers external events, such as the switching of an input or the triggering of a sensor, and then executes predefined actions. These actions can be simple tasks such as switching on a relay or sending a CAN message.

The advantages:

Independent processing – Control takes place directly on the module, independently of the host system.
Flexibly customizable – you can link any inputs and outputs together.
Complex logic possible – Thanks to logical operators such as AND, OR or NOT, even more sophisticated controls can be implemented.
Simple configuration – events and actions are conveniently defined via our ICT-Tool and transferred to the module without any programming knowledge.

Example:
A digital input detects the opening of a door. The system then automatically switches on a light without a PC being involved.

Modulauswahl
Hier können Sie Ihre Module mit einem Klick auf das „+“ Symbol ins ICT-Tool einbinden, um diese anschließend konfigurieren oder testen zu können.

Modulserien, die von dieser Funktion unterstützt werden:

BS-USB2-Serie
BS-WEU-Serie
NET-Serie
UC-Serie
CAN-Box

Modulserien, die von dieser Funktion nicht unterstützt werden:

Starter-Serie
RO-Serie
COS-Serie

Our ICT-Tool in the “Statistics” section provides a quick overview of all current campaigns and events.

Eine mini SPS
Um unsere Module noch kundenfreundlicher und flexibler zu gestalten und Ihnen den Einstieg in die Welt der automatisierten Steuer- und Regelungstechnik zu erleichtern, haben wir als neues Feature das sog. Event-Control in unsere Produkte implementiert. Mit dieser Funktion lassen sich kleine Steueraufgaben in das Modul speichern, die anschließend nach dem „Wenn-Dann“ Prinzip automatisch Aktionen ausführen.

The following information can be taken from the statistics:

Executed event no.
Event mode
Interval
Number of events executed
Number of the executed action
Number of actions performed

Modulserien, die von dieser Funktion unterstützt werden:

BS-USB2-Serie
BS-WEU-Serie
NET-Serie
UC-Serie
CAN-Box

Modulserien, die von dieser Funktion nicht unterstützt werden:

Starter-Serie
RO-Serie
COS-Serie

An event is used to execute a specific action as soon as a condition is met.
A time period can also be specified for how long the condition must be fulfilled in order to execute an action.
These settings are saved directly in the Module-Configuration-Memory of the module.
Example: Voltages can be automatically output via the D/A converter or relays can be switched when a previously defined switching threshold is reached at the A/D inputs or a signal is detected at a digital input.

Depending on the features of your product, you can choose from different modes:

“DI” / “DI flip-flop” / “DO readback”
DI: High or low signal of a digital input.
Flip-Flop: If the status of the digital input changes, the flip-flop of the channel is set and then reset again.
DO-Readback: The status of the output channel is read out.

The following settings can be made:

Number of the channel to be monitored
Condition of the channel status (on = 1 / off = 0)
Minimum time to wait until the action is triggered
Number of the action to be executed (this is configured in the Action area)

“A/D”
The voltage currently present at the analog input is read out.

The following settings can be made:

Number of the channel to be monitored
A/D mode (selection depends on module)
Condition that must be fulfilled (value greater than … , value less than … , value in a range)
Values that must be achieved for the condition
Minimum time to wait until the action is triggered
Number of the action to be executed (this is configured in the Action area)

In the “Actions” section of our ICT-Tool, you define which tasks are to be performed automatically as soon as a condition (“event”) is fulfilled.
For example, you can specify that a certain CAN packet should be sent when a certain voltage is measured on an A/D channel or a signal is detected at a digital input.

Depending on the features of your product, you can choose from different modes:

Folgende Informationen können der Statistik entnommen werden:

Ausgeführte Event-Nr.
Event-Modus
Intervall
Anzahl ausgeführter Events
Nummer der ausgeführten Aktion
Anzahl ausgeführter Aktionen

“Set D/A output”
Outputs a voltage or a current at an analog output.

The following settings can be made:

Number of the channel on which the action is to be executed
D/A mode (selection depends on module)
Voltage or current to be output
Time to wait before executing the action again

“Set DO output”
Switches a digital output on or off.

The following settings can be made:

Number of the channel to be controlled
State (0 = off / 1 = on) that is to be set
Time to wait before executing the action again

“Send CAN package”
The set CAN TX event is triggered. For this function, the trigger mode in the CAN TX package must be set to “TX-EVENT” (see configuration).

The following settings can be made:

Number of the CAN TX event to be triggered
Time to wait before executing the action again (prevents a CAN packet from being sent too frequently)

You can find more information on configuring TX mode here:

Management functions

DapiOpenModule

This function opens a specific module.

Description
This function opens a specific module.

Definition
ULONG DapiOpenModule(ULONG moduleID, ULONG nr);

Parameter
moduleID=Specifies the module to be opened (see delib.h)
nr=Specifies which module is to be opened.
nr=0 -> 1. Module
nr=1 -> 2. Module

Return value
handle=Corresponding handle for the module
handle=0 -> Module was not found

Remark
The handle returned by this function is required to identify the module for all other functions.

Programming example

// Open USB module
handle = DapiOpenModule(RO_USB1, 0);
printf(„handle = %x\n“, handle);
if (handle==0)
{
// USB module was not found
printf(„Module could not be opened\n“);
return;
}

DapiCloseModule

This command closes an open module.

Description
This command closes an open module.

Definition
ULONG DapiCloseModule(ULONG handle);

Parameter
handle=This is the handle of an open module

Return value
None

Programming example

// Close module
DapiCloseModule(handle);

DapiGetDELIBVersion

This function returns the installed DELIB version.

Description
This function returns the installed DELIB version.

Definition
ULONG DapiGetDELIBVersion(ULONG mode, ULONG par);

Parameter
mode=Mode with which the version is read out (must always be 0).
par=This parameter is not defined (must always be 0).

Return value
version=Version number of the installed DELIB version [hex]

Programming example

version = DapiGetDELIBVersion(0, 0);
//With version 1.32 installed
version = 132(hex)

DapiSpecialCMDGetModuleConfig

This function returns the hardware configuration (number of input and output channels) of the module.

Description
This function returns the hardware configuration (number of input and output channels) of the module.

Definition
ULONG DapiSpecialCommand(ULONG handle,
DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, par, 0, 0);

Parameter
handle=This is the handle of an open module
Querying the number of digital input channels
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI
Query number of digital input flip-flops
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI_FF
Query number of digital input counters (16-bit counter)
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI_COUNTER
Query number of digital input counters (48-bit counter)
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_CNT48
Querying the number of digital output channels
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DO
Querying the number of digital pulse generator outputs
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_PULSE_GEN
Querying the number of digital PWM outputs
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_PWM_OUT
Querying the number of digital input/output channels
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DX
Querying the number of analog input channels
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_AD
Querying the number of analog output channels
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DA
Query number of temperature channels
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_TEMP
Query number of stepper channels
par=DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_STEPPER

Return value
Querying the number of digital input channels
return=number of digital input channels
Query number of digital input flip-flops
return=number of digital input flip-flops
Query number of digital input counters (16-bit counter)
return=number of digital input counters (16-bit counter)
Query number of digital input counters (48-bit counter)
return=number of digital input counters (48-bit counter)
Querying the number of digital output channels
return=number of digital output channels
Querying the number of digital pulse generator outputs
return=number of digital pulse generator outputs
Querying the number of digital PWM outputs
return=number of digital PWM outputs
Querying the number of digital input/output channels
return=number of digital input/output channels
Querying the number of analog input channels
return=number of analog input channels
Querying the number of analog output channels
return=number of analog output channels
Query number of temperature channels
return=number of temperature channels
Query number of stepper channels
return=number of stepper channels

Programming example

ret=DapiSpecialCommand(handle,
DAPI_SPECIAL_CMD_GET_MODULE_CONFIG,
DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI, 0, 0);
//Returns the number of digital input channels
ret=DapiSpecialCommand(handle,
DAPI_SPECIAL_CMD_GET_MODULE_CONFIG,
DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DO, 0, 0);
//Returns the number of digital output channels
ret=DapiSpecialCommand(handle,
DAPI_SPECIAL_CMD_GET_MODULE_CONFIG,
DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DX, 0, 0);
//Returns the number of digital input/output channels
ret=DapiSpecialCommand(handle,
DAPI_SPECIAL_CMD_GET_MODULE_CONFIG,
DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_AD, 0, 0);
//Returns the number of analog input channels
ret=DapiSpecialCommand(handle,
DAPI_SPECIAL_CMD_GET_MODULE_CONFIG,
DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DA, 0, 0);
//Returns the number of analog output channels
ret=DapiSpecialCommand(handle,
DAPI_SPECIAL_CMD_GET_MODULE_CONFIG,
DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_STEPPER, 0, 0);
//Returns the number of stepper channels

DapiOpenModuleEx

This function specifically opens a module with an Ethernet interface. The parameters IP address, port number and the duration of the timeout can be defined.

Description
This function specifically opens a module with an Ethernet interface. The parameters IP address, port number and the duration of the timeout can be defined. The module is opened independently of the settings made in the DELIB Configuration Utility.

Definition
ULONG DapiOpenModuleEx(ULONG moduleID, ULONG nr, unsigned char* exbuffer, 0);

Parameter
moduleID = Specifies the module to be opened (see delib.h)
nr = Specifies which module (if several) is to be opened.
nr = 0 -> 1. Module
nr = 1 -> 2. Module
exbuffer = Buffer for IP address, port number and duration of the timeout

Return value
handle = Corresponding handle for the module
handle = 0 -> Module was not found

Remark
The handle returned by this function is required to identify the module for all other functions.
This command is supported by all modules with an Ethernet interface.

Programming example

// Open ETH-Module with parameter

DAPI_OPENMODULEEX_STRUCT open_buffer;

strcpy((char*) open_buffer.address, "192.168.1.10");
open_buffer.portno = 0;
open_buffer.timeout = 5000;

handle = DapiOpenModuleEx(RO_ETH, 0, (unsigned char*) &open_buffer, 0);
printf("Module handle = %x\n", handle);

DapiScanAllModulesAvailable

This function can be used to scan all modules connected to the USB bus.

Description
This function can be used to scan all modules connected to the USB bus.
The module ID and module no. of each module found are determined.

Definition
ULONG DapiScanAllModulesAvailable(uint nr)

Parameter
nr = 0: All modules connected to the USB bus are searched for
nr = i: Reading out the individual connected modules

Return value
Indicates the number of modules found.

Programming example

no_of_modules =
DT.Delib.DapiScanAllModulesAvailable(0);
for (i = 1; i <= no_of_modules; i++)
{
ret = DapiScanAllModulesAvailable(i);
moduleID = ret & 0x0000ffff;
moduleNr = (ret >> 16) & 0xff;
}

Register functions

DapiWriteByte

This command executes a direct register write command to the module.

Description
This command executes a direct register write command to the module.

Definition
void DapiWriteByte(ULONG handle, ULONG adress, ULONG value);

Parameter
handle=This is the handle of an open module
adress=Address to be accessed
value=Specifies the data value that is written (8-bit)

Return value
None

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programming example

// Data is written to register 0x10
DapiWriteByte(handle, 0x10, 0xFF);

DapiWriteWord

This command executes a direct register write command to the module.

Description
This command executes a direct register write command to the module.

Definition
void DapiWriteWord(ULONG handle, ULONG adress, ULONG value);

Parameter
handle=This is the handle of an open module
adress=Address to be accessed
value=Specifies the data value that is written (16-bit)

Return value
None

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programming example

// Data is written to register 0x10
DapiWriteWord(handle, 0x10, 0xFFFF);

DapiWriteLong

This command executes a direct register write command to the module.

Description
This command executes a direct register write command to the module.

Definition
void DapiWriteLong(ULONG handle, ULONG adress, ULONG value);

Parameter
handle=This is the handle of an open module
adress=Address to be accessed
value=Specifies the data value that is written (32-bit)

Return value
None

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programming example

// Data is written to register 0x10
DapiWriteLong(handle, 0x10, 0xFFFFFFFF);

DapiWriteLongLong

This command executes a direct register write command to the module.

Description
This command executes a direct register write command to the module.

Definition
void DapiWriteLongLong(ULONG handle, ULONG adress, ULONGLONG value);

Parameter
handle=This is the handle of an open module
adress=Address to be accessed
value=Specifies the data value that is written (64-bit)

Return value
None

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programming example

// Data is written to register 0x10
DapiWriteLongLong(handle, 0x10, 0xFFFFFFFFFFFFFFFF);

DapiReadByte

This command executes a direct register read command on the module.

Description
This command executes a direct register read command on the module.

Definition
ULONG DapiReadByte(ULONG handle, ULONG adress);

Parameter
handle=This is the handle of an open module
adress=Address to be accessed

Return value
Content of the register to be read (8-bit)

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programmierbeispiel

// Reads 8 bits from the address 0x0
ULONG data;
data = DapiReadByte(handle, 0x0);

DapiReadWord

This command executes a direct register read command on the module.

Description
This command executes a direct register read command on the module.

Definition
ULONG DapiReadWord(ULONG handle, ULONG adress);

Parameter
handle=This is the handle of an open module
adress=Address to be accessed

Return value
Content of the register to be read (16-bit)

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programming example

// Reads 16 bits from the address 0x0
ULONG data;
data = DapiReadWord(handle, 0x0);

DapiReadLong

This command executes a direct register read command on the module.

Description
This command executes a direct register read command on the module.

Definition
ULONG DapiReadLong(ULONG handle, ULONG adress);

Parameter
handle=This is the handle of an open module
adress=Address to be accessed

Return value
Content of the register to be read (32-bit)

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programming example

// Reads 32 bits from the address 0x0
ULONG data;
data = DapiReadLong(handle, 0x0);

DapiReadLongLong

This command executes a direct register read command on the module.

Description
This command executes a direct register read command on the module.

Definition
ULONGLONG DapiReadLongLong(ULONG handle, ULONG address);

Parameter
handle=This is the handle of an open module
address=Address to be accessed

Return value
Content of the register to be read (64-bit)

Remark
This should only be used by experienced programmers. This allows direct access to all available registers.

Programming example

// Reads 64 bits from the address 0x0
ULONGLONG data;
data = DapiReadLongLong(handle, 0x0);

Digital input counter

DapiDIGet1

This command reads a single digital input.

Description
This command reads a single digital input.

Definition
ULONG DapiDIGet1(ULONG handle, ULONG ch);

Parameter
handle=This is the handle of an open module
ch=Indicates the number of the input to be read (0, 1, 2, 3, .. )

Return value
State of the input (0/1)

Requirements
The following SW feature bits must be supported by the module:

DAPI_SW_FEATURE_BIT_CFG_DI

The following conditions for the transfer parameters must be met:

maxCh = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI, 0, 0);
maxCh > ch

Programming example

// Read out 1 channel
unsigned long data;
data = DapiDIGet1(handle, 0);

DapiDIGet8

This command reads 8 digital inputs simultaneously.

Description
This command reads 8 digital inputs simultaneously.

Definition
ULONG DapiDIGet8(ULONG handle, ULONG ch);

Parameter
handle=This is the handle of an open module
ch=Specifies the number of the input from which to read (0, 8, 16, 24, .. )

Return value
State of the read inputs.

Requirements
The following SW feature bits must be supported by the module:

DAPI_SW_FEATURE_BIT_CFG_DI

The following conditions for the transfer parameters must be met:

maxCh = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI, 0, 0);
maxCh > ch (ch must be 0, 8, 16, ...)

Programming example

// Read out 8 channels
unsigned long data;
data = DapiDIGet8(handle, 0);

DapiDIGet16

This command reads 16 digital inputs simultaneously.

Description
This command reads 16 digital inputs simultaneously.

Definition
ULONG DapiDIGet16(ULONG handle, ULONG ch);

Parameter
handle=This is the handle of an open module
ch=Specifies the number of the input from which to read (0, 16, 32, ...)

Return value
State of the read inputs.

Requirements
The following SW feature bits must be supported by the module:

DAPI_SW_FEATURE_BIT_CFG_DI

The following conditions for the transfer parameters must be met:

maxCh = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI, 0, 0);
maxCh > ch (ch must be 0, 16, 32, ...)

Programming example

// Read out 16 channels
unsigned long data;
data = DapiDIGet16(handle, 0);

DapiDIGet32

This command reads 32 digital inputs simultaneously.

Description
This command reads 32 digital inputs simultaneously.

Definition
ULONG DapiDIGet32(ULONG handle, ULONG ch);

Parameter
handle=This is the handle of an open module
ch=Specifies the number of the input from which to read (0, 32, 64, ..)

Return value
State of the read inputs.

Requirements
The following SW feature bits must be supported by the module:

DAPI_SW_FEATURE_BIT_CFG_DI

The following conditions for the transfer parameters must be met:

maxCh = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI, 0, 0);
maxCh > ch (ch must be 0, 32, 64, ...)

Programming example

unsigned long data;
// ----------------------------------------------------
// Read a value from the inputs (Eingang 1-31)
data = (unsigned long) DapiDIGet32(handle, 0);
// Chan Start = 0
printf("Input 0-31 : 0x%x\n", data);
printf("Press any key to continue\n");
getch();
// ----------------------------------------------------
// Read a value from the inputs (input 32-64)
data = (unsigned long) DapiDIGet32(handle, 32);
// Chan Start = 32
printf("Input 32-64 : 0x%x\n", data);
printf("Press any key to continue\n");
getch();

DapiDIGet64

This command reads 64 digital inputs simultaneously.

Description
This command reads 64 digital inputs simultaneously.

Definition
ULONGLONG DapiDIGet64(ULONG handle, ULONG ch);

Parameter
handle=This is the handle of an open module
ch=Specifies the number of the input from which to read (0, 64, ..)

Return value
State of the read inputs.

Requirements
The following SW feature bits must be supported by the module:

DAPI_SW_FEATURE_BIT_CFG_DI

The following conditions for the transfer parameters must be met:

maxCh = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI, 0, 0);
maxCh > ch (ch must be 0 or 64)

Programming example

// Read out 64 channels
ULONGLONG data;
data = DapiDIGet64(handle, 0);

DapiDIGetFF32

This command reads the flip-flops of the inputs and resets them.

Description
This command reads the flip-flops of the inputs and resets them.

Definition
ULONG DapiDIGetFF32(ULONG handle, ULONG ch);

Parameter
handle=This is the handle of an open module
ch=Specifies the number of the input from which to read (0, 32, 64, ..)

Return value
Status of 32 input status changes.

Requirements
The following SW feature bits must be supported by the module:

DAPI_SW_FEATURE_BIT_CFG_DI_FF

The following conditions for the transfer parameters must be met:

maxCh = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI_FF, 0, 0);
maxCh > ch (ch must be 0, 32, 64, ...)

DapiDIGetCounter

This command reads the input counter of a digital input.

Description
This command reads the input counter of a digital input.

Definition
ULONG DapiDIGetCounter(ULONG handle, ULONG ch, ULONG mode);

Parameter
handle=This is the handle of an open module.
ch=Specifies the number of the input from which to read.
mode=0 (normal counting function)
mode=DAPI_CNT_MODE_READ_WITH_RESET (read counter and reset counter directly)
mode=DAPI_CNT_MODE_READ_LATCHED (read out the stored counter reading)

Return value
Output of the counter value.

Requirements
The following SW feature bits must be supported by the module:

DAPI_SW_FEATURE_BIT_CFG_DI_CNT

The following conditions for the transfer parameters must be met:

maxCh = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_GET_MODULE_CONFIG, DAPI_SPECIAL_GET_MODULE_CONFIG_PAR_DI_COUNTER, 0, 0);
maxCh > ch

Programming example

value = DapiDIGetCounter(handle, 0 ,0); // Counter of DI Chan 0 is read
value = DapiDIGetCounter(handle, 1 ,0); // Counter of DI Chan 1 is read
value = DapiDIGetCounter(handle, 8 ,0); // Counter of DI Chan 8 is read
value = DapiDIGetCounter(handle, 0 ,DAPI_CNT_MODE_READ_WITH_RESET); // Counter of DI Chan 0 is read AND reset
value = DapiDIGetCounter(handle, 1, DAPI_CNT_MODE_READ_LATCHED); // Reading the stored meter reading from DI Chan 1

DapiSpecialCommand - DapiSpecialCounterLatchAll

This command saves the counter readings of all input counters simultaneously in a buffer (latch).

Description
This command saves the counter readings of all input counters simultaneously in a buffer (latch).
This allows all counter readings of the latch to be read out one after the other.
A special feature here is that it is possible to "freeze" the meter readings at the same time and the frozen readings (latch) can then be read out one after the other.

Definition
void DapiSpecialCommand(ULONG handle, DAPI_SPECIAL_CMD_COUNTER, DAPI_SPECIAL_COUNTER_LATCH_ALL, 0, 0);

Parameter
handle=This is the handle of an open module.
mode=DAPI_SPECIAL_CMD_COUNTER (It is a counter command)
mode=DAPI_SPECIAL_COUNTER_LATCH_ALL (Freezes all counter inputs and makes them available as a latch)

Remark
This command is only supported by our RO-O8-R8 time modules!

Programming example

DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_COUNTER, DAPI_SPECIAL_COUNTER_LATCH_ALL, 0, 0);

DapiSpecialCommand - DapiSpecialCounterLatchAllWithReset

This command saves the counter readings of all input counters simultaneously in a buffer (latch). In addition, the counter readings of the input counters are subsequently reset.

Description
This command saves the counter readings of all input counters simultaneously in a buffer (latch). In addition, the counter readings of the input counters are subsequently reset.

Definition
void DapiSpecialCommand(ULONG handle, DAPI_SPECIAL_CMD_COUNTER, DAPI_SPECIAL_COUNTER_LATCH_ALL_WITH_RESET, 0, 0);

Parameter
handle=This is the handle of an open module.
mode=DAPI_SPECIAL_CMD_COUNTER (It is a counter command)
mode=DAPI_SPECIAL_COUNTER_LATCH_ALL_WITH_RESET (Freezes all counter inputs and makes them available as a latch and resets the counter of the input channels)

Remark
This command is only supported by our RO-O8-R8 time modules!

Programming example

DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_COUNTER, DAPI_SPECIAL_COUNTER_LATCH_ALL_WITH_RESET, 0, 0);

DapiSpecialCommand - DapiSpecialDIFilterValueSet

This command sets a filter [ms] in which time interval digital input channels are sampled.

Description
This command sets a filter [ms] in which time interval digital input channels are sampled.

Definition
DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FILTER_VALUE_SET, ULONG time_ms, 0);

Parameter
handle=This is the handle of an open module
time_ms=Time interval [ms] in which digital input channels are sampled.

Remark
This command only supports pulse times between 5ms and 255ms.
If no time is set, the default value is 100ms.
This command is not supported by our modules with Ethernet interface

Programming example

DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FILTER_VALUE_SET, 5, 0);
// Sets the time interval to 5ms
DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FILTER_VALUE_SET, 150, 0);
// Sets the time interval to 150ms

DapiSpecialCommand - DapiSpecialDIFilterValueGet

This command returns the previously defined value of the time interval for sampling the digital input channels in [ms].

Description
This command returns the previously defined value of the time interval for sampling the digital input channels in [ms].

Definition
ULONG DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FILTER_VALUE_GET, 0, 0);

Parameter
handle=This is the handle of an open module

Return value
Time [ms]

Remark
This command is not supported by our modules with Ethernet interface.

Programming example

value = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FILTER_VALUE_GET, 0, 0);
//Returns the time interval for scanning the digital input channels.

DapiSpecialCommand - Dapi_Special_DI_FF_Filter_Value_Set

This command sets a filter [ms] in which time interval the input flip-flops and the input counters are queried.

Description
This command sets a filter [ms] in which time interval the input flip-flops and the input counters are queried.

Definition
void DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FF_FILTER_VALUE_SET, ULONG time_ms, 0);

Parameter
handle=This is the handle of an open module
time_ms=Time interval [ms] in which digital input channels are sampled.

Remark
This command only supports pulse times between 5ms and 255ms.
If no time is set, the default value is 100ms.
This command is not supported by our modules with Ethernet interface.

Programming example

DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FF_FILTER_VALUE_SET, 5, 0);
// Sets the time interval to 5ms
DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI,
DAPI_SPECIAL_DI_FF_FILTER_VALUE_SET, 150, 0);
// Sets the time interval to 150ms

DapiSpecialCommand - Dapi_Special_DI_FF_Filter_Value_Get

This command returns the previously defined value of the time interval for sampling the input flip-flops and the input counters in [ms].

Description
This command returns the previously defined value of the time interval for sampling the input flip-flops and the input counters in [ms].

Definition
ULONG DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FF_FILTER_VALUE_GET, 0, 0);

Parameter
handle=This is the handle of an open module

Return value
Time [ms]

Remark
This command is not supported by our modules with Ethernet interface.

Programming example

value = DapiSpecialCommand(handle, DAPI_SPECIAL_CMD_DI, DAPI_SPECIAL_DI_FF_FILTER_VALUE_GET, 0, 0);
//Returns the time interval for scanning the digital input channels.

Error handling

DapiGetLastError

This function returns the last error recorded.

Description
This function returns the last recorded error. If an error has occurred, it must be cleared with DapiClearLastError(), otherwise every call to DapiGetLastError() will return the "old" error.
If several modules are to be used, the use of DapiGetLastErrorByHandle() is recommended.

Definition
ULONG DapiGetLastError(void);

Parameter
None

Return value
Error code
0=no error. (see delib_error_codes.h)

Programming example

BOOL IsError()
{
unsigned char msg[500];
unsigned long error_code = DapiGetLastError();

if (error_code != DAPI_ERR_NONE)
{
DapiGetLastErrorText((unsigned char*) msg, sizeof(msg));
printf("Error Code = 0x%x * Message = %s\n", error_code, msg);

DapiClearLastError();

return TRUE;
}

return FALSE;
}

DapiGetLastErrorByHandle

This function returns the last error recorded for a specific module using the handle.

Description
This function returns the last error recorded for a specific module using the handle. If an error has occurred, it must be cleared with DapiClearLastErrorByHandle(), otherwise every call to DapiGetLastErrorByHandle() will return the "old" error.

Definition
ULONG DapiGetLastErrorByHandle(ULONG handle);

Parameter
handle=This is the handle of an open module

Return value
Error code
0=no error. (see delib_error_codes.h)

Programming example

BOOL IsError(ULONG handle)
{
unsigned long error_code = DapiGetLastErrorByHandle(handle);

if (error_code != DAPI_ERR_NONE)
{
printf("Error detected on handle 0x%x - Error Code = 0x%x\n", handle, error_code);

DapiClearLastErrorByHandle(handle);

return TRUE;
}

return FALSE;
}

DapiGetLastErrorText

This function reads out the text of the last error recorded.

Description
This function reads out the text of the last recorded error. If an error has occurred, it must be cleared with DapiClearLastError(), otherwise every call to DapiGetLastErrorText() will return the "old" error.

Definition
ULONG DapiGetLastErrorText(unsigned char * msg, unsigned long msg_length);

Parameter
msg = Buffer for the text to be received
msg_length = Length of the text buffer

Programming example

BOOL IsError()
{
unsigned char msg[500];
unsigned long error_code = DapiGetLastError();

if (error_code != DAPI_ERR_NONE)
{
DapiGetLastErrorText((unsigned char*) msg, sizeof(msg));
printf("Error Code = 0x%x * Message = %s\n", error_code, msg);

DapiClearLastError();

return TRUE;
}

return FALSE;
}

DapiClearLastError

This function deletes the last error that was recorded with DapiGetLastError().

Description
This function deletes the last error that was recorded with DapiGetLastError().

Definition
void DapiClearLastError(void);

Parameter
None

Return value
None

Programming example

BOOL IsError()
{
unsigned char msg[500];
unsigned long error_code = DapiGetLastError();

if (error_code != DAPI_ERR_NONE)
{
DapiGetLastErrorText((unsigned char*) msg, sizeof(msg));
printf("Error Code = 0x%x * Message = %s\n", error_code, msg);

DapiClearLastError();

return TRUE;
}

return FALSE;
}

DapiClearLastErrorByHandle

This function deletes the last error of a specific module (handle) that was recorded with DapiGetLastErrorByHandle().

Description
This function deletes the last error of a specific module (handle) that was registered with DapiGetLastErrorByHandle().

Definition
void DapiClearLastErrorByHandle(ULONG handle);

Parameter
handle=This is the handle of an open module.

Return value
None

Programming example

BOOL IsError(ULONG handle)
{
unsigned long error_code = DapiGetLastErrorByHandle(handle);

if (error_code != DAPI_ERR_NONE)
{
printf("Error detected on handle 0x%x - Error Code = 0x%x\n", handle, error_code);

DapiClearLastErrorByHandle(handle);

return TRUE;
}

return FALSE;
}

Test functions

DapiPing

This command checks the connection to an open module.

Description
This command checks the connection to an open module.

Definition
ULONG DapiPing(ULONG handle, ULONG value);

Parameter
handle=This is the handle of an open module
value=Transferred test value, in the value range of 0-255 (8-bit), to the module

Return value
The test value transferred with "value" must be returned here

Connection example DI:

Screwless connector system

The customer-side connection wiring of the inputs and outputs is carried out using screwless, pluggable terminal strips. The conductor connection is made using a so-called actuating tool.
A locking and ejecting mechanism facilitates the insertion and removal of the complete terminal strip.

Handling:

Steps 1-5

Step 1

See the scope of delivery for the operating tool.

Step 2

Insert the operating tool firmly into the side opening in the direction of the conductor connection.

Step 3

Now insert the stripped conductor into the open clamp contact.

Step 4

Pull out the operating tool again.

Step 5

Check that the conductor is properly connected. It should now no longer be possible to pull it out easily.

Manual

Manual UC series

Download

Quickstart - Hardware description - Software description - ICT-Tool

Commissioning/Quickstart

Safety instructions
Installing the drivers
Connecting the power supply
Connecting to the PC or network
Connecting the I/O connectors
Function test

Hardware description

List of technical data
Definition of the LEDs
Functions of switches and buttons
Pin assignment of the connectors
Connection examples

Software description

Control options via the DELIB, protocol level, DELIB CLI, graphical applications
DELIB Driver Library, DELIB Sample Sources, DELIB for Linux
Web interface (only for Ethernet modules)
DELIB API and its functions

ICT-Tool

Add module on the PC
Configure module/interface (Ethernet, USB, CAN, serial)
Setting options for M2M and event control (only for supported modules)
Test and diagnose module
Install firmware updates
Save/load module configurations using a separate file

Software packages ICT-Tool / DELIB driver library

ICT-Tool + DELIB for Windows (64-bit)

Download

For Windows 11/10, Windows 7, Windows 8, Vista, XP and 2000

Software package for the 64-bit version of the ICT-Tool and the DELIB driver library.

The following operating systems are compatible:
64-bit:

Windows 10/11 x64
Windows 8 x64
Windows 7 x64
Windows Server 2012 x64
Windows Server 2008 x64
Windows Vista x64
Windows XP x64
Windows Server 2003 x64
Windows 2000 x64

Supplied software

ICT-Tool x64

Updating the DEDITEC module-firmware
Assigning module addresses
Module-specific settings
Configuration of CAN modules
Test and diagnosis of module functions
Configuration of the watchdog stick

Replaces the following software

DT-Flasher x64
DELIB Module Demo x64
CAN Configuration Utility x64
DELIB Module Config x64
DELIB Configuration Utility x64
Watchdog Configuration Utility x64

DELIB Command Line Interface x64

Enables the execution of DELIB commands in the command line.

ICT-Tool + DELIB for Windows (32-bit)

Download

For Windows 11/10, Windows 7, Windows 8, Vista, XP and 2000

Software package for the 32-bit version of the ICT-Tool and the DELIB driver library.

The following operating systems are compatible:
32-bit:

- - Windows 10/11
  - Windows 8
  - Windows 7
  - Windows Server 2012
  - Windows Server 2008
  - Windows Vista
  - Windows XP
  - Windows Server 2003
  - Windows 2000

Supplied software

ICT-Tool x32

- - Updating the DEDITEC module-firmware
  - Assigning module addresses
  - Module-specific settings
  - Configuration of CAN modules
  - Test and diagnosis of module functions
  - Configuration of the watchdog stick

Replaces the following software

- - DT-Flasher
  - DELIB Module Demo
  - CAN Configuration Utility
  - DELIB Module Config
  - DELIB Configuration Utility
  - Watchdog Configuration Utility

Attention:

With this version of the driver library, only 32-bit applications can be created, which can then be executed on 32- and 64-bit systems.

DELIB driver library for Linux (32/64-bit)

Download

For 32/64-bit Linux distributions from kernel 2.6.x. Version 2.73 from 28.10.2024

DELIB driver library for Linux distributions (32/64-bit) from kernel 2.6.x

This driver package contains the following components

DELIB USB driver
DELIB Ethernet driver
DELIB CLI

DELIB USB driver

Support for the following products:

NET series (via USB interface)
RO-USB series
BS-USB series
USB mini-sticks
USB watchdog
USB-OPTION-8 / USB-RELAY-8
USB-TTL-32 / USB-TTL-64

Note:

With the standard version of the USB driver, several USB products with different module IDs (e.g. one RO-USB and one USB-OPTOIN-8) can be addressed. No further driver installation is required.

If several USB products with the same module ID (e.g. a USB-OPTOIN-8 and a USB-RELAIS-8) are to be addressed, the Linux FTDI driver must also be installed. You can find the FTDI driver at http://www.ftdichip.com.

DELIB Ethernet driver

Support for the following products:

NET series (via Ethernet interface)
RO-ETH series
RO-ETH/LC series
BS-ETH series
ETH-OPTION-8 / ETH-RELAY-8
ETH-TTL-64

DELIB CLI

With the DELIB CLI (Command Line Interface) for Linux, all commands for digital and analog I/Os can be set directly via the command line

Manual

Manual for ICT-Tool and DELIB

Download

Software Description - ICT-Tool - DELIB API Reference

Software Description

Control options via DELIB, protocol level, DELIB CLI, graphical applications
DELIB driver library, DELIB sample sources, DELIB for Linux
Web interface (only for Ethernet modules)
DELIB API and its functions

ICT-Tool

Add module to PC
Configure module/interface (Ethernet, USB, CAN, Serial)
Settings for M2M and Event Control (only for supported modules)
Test and diagnose module
Install firmware updates
Save/load module configurations using a separate file

DELIB API Reference

Directory structure of DELIB
Management functions
Error handling
Manage digital inputs and outputs
Manage analog inputs and outputs
Manage software FIFO
Manage output timeout
Register read and write commands

Download

Hardware updates (firmware flash file package)

Download

Firmware flash file package for the ICT tool

This package contains the latest firmware files for the following product series:

STARTER series
BS series
RO series
NET series
UC series
CAN-IO-Box
Development accessories

The firmware flash file package can alternatively be downloaded via the ICT tool.

USB cable A plug to C plug

USB cable for connecting our modules to the control PC.

Type: USB 2.0, A plug to C plug
Length: 1 m

To the product

5-pin plug connector

Enables the power supply to be connected to the DEDITEC module.

Type: Phoenix Contact® - 1876343
100 % mismatch protected
For all conductor types from 0.2 mm² to 2.5 mm²

To the product

16-pin plug connector

Required for connecting inputs and outputs of the DEDITEC module.

Type: WAGO® 713-1108/037-000
Plug-in female multipoint connector with locking mechanism
100 % mismatch protected
1-wire connection for all conductor types up to 1.5 mm²

To the product

Actuating tool for Wago connectors

Used to open and close the terminal contacts on the WAGO® connectors.

Type: WAGO® - 734-231

To the product

Optional input voltage range 5 V ... 15 V

This option reduces the input voltage range of the OPTOIN modules to 5 V to 15 V. 8 channels per ordered quantity are always modified.

Input voltage range 5 V to 15 V AC / DC
8 channels

To the product

USB cable A plug to C plug

USB cable for connecting our modules to the control PC.

Type: USB 2.0, A plug to C plug
Length: 1 m

To the product

5-pin plug connector

Enables the power supply to be connected to the DEDITEC module.

Type: Phoenix Contact® - 1876343
100 % mismatch protected
For all conductor types from 0.2 mm² to 2.5 mm²

To the product

16-pin plug connector

Required for connecting inputs and outputs of the DEDITEC module.

Type: WAGO® 713-1108/037-000
Plug-in female multipoint connector with locking mechanism
100 % mismatch protected
1-wire connection for all conductor types up to 1.5 mm²

To the product

Actuating tool for Wago connectors

Used to open and close the terminal contacts on the WAGO® connectors.

Type: WAGO® - 734-231

To the product

Strain relief plate for 16 or 18-pin Wago connectors

The strain relief plate is pushed onto the center of the female connector and enables the connected cables or strands to be fixed in place.

Type: WAGO® - 713-127
Strain relief for the connection wiring
Suitable for 16 or 18-pole female connectors
Slide onto the female connector from the side

To the product

Top hat rail

Top-hat rail for mounting our control technology modules.

DIN rail according to DIN EN 50022
Type: Phoenix Contact® - 1208131
Dimensions in mm: 450 x 35 x 7.5 (L x W x H)

To the product

24V/2A power supply unit for top-hat rail mounting

The DR-4524 from Mean Well is a 48W power supply unit for DIN rail mounting for industrial applications. It offers protection against short circuit, overload, overvoltage and overheating.

Input voltage range: 85 V.. 264 V AC / 120 V DC ... 370 V DC
Output voltage: 24 V DC
Output current: 2 A
Rated power: 48 W

To the product

230 V top-hat rail relay

PLC interface for limit continuous currents up to 10 A, consisting of basic terminal with screw connection and plug-in miniature relay. Can be mounted on NS 35/7.5 mounting rail.

Rated voltage: 230 V AC / 230 V DC
Switching voltage: 250 V AC/DC
1 Changer
Reverse polarity protection, freewheeling diode
LED for voltage display
Type: Phoenix Contact® - 2967675, PLC-RSC-230UC/21HC

To the product

Typical Application Areas:

Smart Building & Building Automation:
The control of lighting, air conditioning systems, blinds, or security systems is carried out centrally via USB using the module.
Decentralized I/O expansion of existing systems:
Scalable extension of control architectures through modular USB I/O components directly at the machine environment.

Comparison of UC-USB-O16 with common market products

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Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Interfaces & Communication
USB Standard	usually only USB-A / B	Thanks to USB-C, it is significantly more modern and faster than typical USB I/O boards	Improves compatibility with current devices and simplifies integration.
Number of USB modules that can be used simultaneously	1–4 modules, often without proper management	Up to 16 modules per system	Enables larger system configurations without additional distributors or expansion devices.
Digital inputs
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Counter function per channel	Often only simple status queries or a global counting function.	16-bit counters per channel with up to 65,535 count cycles.	Enables direct capture of pulses and events without additional hardware.
Wide voltage range	Usually only positive voltage levels are allowed.	Positive and negative voltages can be detected	Expands compatibility with various sensor signals and reduces the need for upstream signal conditioning.
Input filter	Filter functions are often fixed or can only be configured to a limited extent.	Programmable filter for input state changes and counter functions.	Reduces bounce and improves the reliable detection of actual switching signals.
Status display	Channel statuses are often only visible to a limited extent or in aggregate.	LED status indicator per input and output channel for quick visual inspection.	Speeds up diagnostics, commissioning, and troubleshooting directly at the module.
Detection of state changes	Signal changes between two readout cycles are sometimes lost in standard modules.	Internal flip-flops detect transitions from low to high and high to low between two readout operations.	Improves event detection for short signal transitions and asynchronous state changes.
Signal isolation of the inputs	Sometimes without galvanic isolation or with reduced protection between the field and logic sides.	Electrically isolated optocoupler inputs for safe signal operation	Increases operational reliability when detecting external switching and sensor signals.
Automation & Diagnostics
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Status monitoring	Partially without visual indicators	LED status indicators per channel for fast diagnostics	Enables rapid on-site status analysis and reduces the effort required for troubleshooting and diagnostics.
Diagnostic tools	Mostly not available	Extensive diagnostic capabilities integrated in the ICT tool	Simplifies commissioning, troubleshooting, and long-term analysis through centralized, integrated diagnostic functions.
Automated control and monitoring	Additional control PC required	Configurable event control enables automated process monitoring without a control PC	Reduces the need for external control logic and enables automated processes directly within the module.
Hardware flexibility
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Supply voltage	Usually fixed (e.g., +24 V)	Flexible +12 V DC … +28 V DC	Facilitates use in various power supply configurations and reduces the need for additional power supplies.
EMC stability	Low-cost OEM modules often susceptible to interference	Industrial‑grade EMC design	Ensures low-interference operation in industrial environments with high electromagnetic interference.
Software & Integration
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Software integration	Limited drivers	DELIB library for C, C++, C#, Java, VB	Simplifies development through standardized programming interfaces and reduces the effort required for custom driver adaptations.
Example programs	Barely available or only upon request	Example programs can be downloaded for free	Accelerates implementation and facilitates the transition to project-specific applications.
Firmware updates	Often paid or limited	Free for life	Ensures long-term functionality and enables improvements without additional licensing costs.
Example code	Fewer languages or restricted examples	Extensive examples for C, C++, C#, Java, VB, LabView	Supports various development environments and facilitates integration into existing software landscapes.
Response times	Partially higher latency with standard I/O	Very fast firmware	Improves real-time performance and enables reliable processing of time-critical signals.
System integration	Proprietary systems complicate integration	Easy integration into PLCs, PCs, and test benches	Facilitates integration into existing automation and test systems without extensive modifications.
Test system integration	Competitors often more expensive or less flexible	Ideal for automotive and test bench applications	Supports reproducible measurement and test procedures and reduces integration effort in complex test bench environments.
Mechanical & physical properties
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Mounting	Depending on the supplier, different or less standard designs may be used.	Mounting on a 35 x 7.5 mm DIN rail for use in control cabinets and decentralized I/O systems.	Enables quick and standards-compliant integration into existing control cabinets.
Reliability
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Long-term availability	Typically 3–5 years	10‑year guaranteed availability	Simplifies long-term plant planning and reduces risks associated with early product discontinuations.
Firmware updates	Often paid or limited	Free for life	Ensures continuous functional improvement without additional operating costs.
ICT tool	Often multiple tools, fewer functions	One tool for commissioning, diagnostics, loopback testing, long‑term simulation	Simplifies commissioning, diagnostics, and testing procedures through a centralized software solution.
Production location	Many manufacturers produce in Asia	Made in Germany	Enables short supply chains, consistent quality assurance, and a reliable supply of spare parts.
MTBF	Low-cost OEM modules with shorter lifespan	High MTBF values	Reduces the probability of failure and increases availability in continuous-operation applications.
Failure rate	Higher failure rates with low‑cost I/O	Very low field failure rates	Minimizes unplanned downtime and reduces maintenance and service costs.
Spare parts availability	Often early discontinuation	Long‑term spare parts availability	Facilitates maintenance and modernization of existing systems over many years.
Service and support
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Support quality	Call centers or external service providers	Direct developer support	Enables fast and technically sound problem-solving without the need to escalate issues through external service providers.
Response time	Sometimes several days	Very fast response, often same day	Reduces downtime and speeds up the restoration of system operations when technical issues arise.
Customization	Rare or very expensive	Custom hardware/firmware possible	Enables project-specific solutions without the need for time-consuming in-house development or additional hardware components.
Documentation	Often minimal or incomplete	Comprehensive and practical documentation	Simplifies commissioning and reduces the need for follow-up inquiries thanks to clearly structured and comprehensive technical documentation.
Consulting	Often only sales support	Technicians instead of general sales staff	Ensures application-oriented support directly tailored to technical requirements.
Economy
Feature	Market Comparison	Advantages of the DEDITEC UC-USB-O16</th >	Practical Benefits of the modules
Price-performance ratio	Major brands significantly more expensive	Very good price‑performance ratio	Reduces total cost per channel and enables cost-effective system expansions.
License costs	Modbus/features often require additional payment	No additional costs for protocols	Simplifies cost planning and prevents unexpected follow-up costs associated with functional or protocol expansions.
Series prices	Large manufacturers often inflexible	Attractive volume pricing	Simplifies budget planning for larger volumes and enables cost-effective scaling of projects.

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UC-USB module with 16 optocoupler inputs

Product Description – USB digital input module with optocouplers for PLC

Reliable USB communication interface for precise system integration

USB control via API commands and integrated driver interface

Galvanically isolated digital inputs with filtering functions for reliable signal acquisition

Event Control – event-based automation

Robust industrial design with a well-engineered connection and mounting architecture

Maintenance and Long-Term Planning