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Contents
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Table of Contents
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Background and system description 03/2014
Programming Guideline for
S7-1200/1500
STEP 7 (TIA Portal)
http://support.automation.siemens.com/WW/view/en/81318674
Related Manuals for Siemens S7-1200
Summary of Contents for Siemens S7-1200
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Page 1
Background and system description 03/2014 Programming Guideline for S7-1200/1500 STEP 7 (TIA Portal) http://support.automation.siemens.com/WW/view/en/81318674… -
Page 2: Warranty And Liability
Siemens recommends strongly that you regularly check for product updates. For the secure operation of Siemens products and solutions, it is necessary to take suitable preventive action (e.g. cell protection concept) and integrate each component into a holistic, state-of-the-art industrial security concept. Third-party products that may be in use should also be considered.
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Page 3: Table Of Contents
Optimized machine code …………..8 Block creation ………………9 Optimized blocks …………….10 2.6.1 S7-1200: Setup of optimized blocks ……….. 10 2.6.2 S7-1500: Setup of optimized blocks ……….. 11 2.6.3 Best possible data storage in the processor on S7-1500 ….12 2.6.4…
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Page 4
3.10.8 Handling of time tags …………….67 Hardware-Independent Programming …………69 Data types of S7-300/400 and S7-1200/1500 ……..69 No bit memory but global data blocks ……….70 Programming of «clock bits» …………… 71 The Most Important Recommendations …………72 Related Literature ……………….. -
Page 5: Preface
This helps you to create a standardized and optimal programming of your automation solutions. The examples described can be universally used for the controllers S7-1200 and S7-1500. Core content of this programming guideline…
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Page 6: S7-1200/1500 Innovations
(FBs), functions (FCs) or data blocks (DBs). I.e. already created S7-300/400 programs can be implemented on S7-1500 and already created LAD, FBD and SCL programs on S7-1200 controller without any problems. Additionally, there are many innovations that make programming easier for you and which allow a powerful and storage-saving code.
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Page 7
STEP 7 Professional (TIA Portal)? http://support.automation.siemens.com/WW/view/en/62101406 PLC migration for S7-1500 with STEP 7 (TIA Portal) V12 http://support.automation.siemens.com/WW/view/en/67858106 Programming recommendations for S7-1200 and S7-1500 with STEP 7 (TIA Portal) V12 http://support.automation.siemens.com/WW/view/en/67582299 Why is it not possible to mix register passing and explicit parameter transfer with… -
Page 8: Programming Languages
How can the constants be defined under STEP 7 V11 in a S7-SCL program? http://support.automation.siemens.com/WW/view/en/58065411 Optimized machine code TIA Portal and S7-1200/1500 allow an optimized runtime performance in any programming language. All languages are compiled the same, directly into the machine code.
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Page 9: Block Creation
2 S7-1200/1500 Innovations 2.5 Block creation Figure 2-3: Machine code generation with S7-300/400/WinAC and S7-1200/1500 S7-1200/1500 S7-300/400/WinAC (only S7-1500) Machine code Machine code S7-1200/1500 S7-300/400/WinAC For S7-300/400/WinAC controllers LAD and FBD programs are first of all compiled in STL before the machine code is created.
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Page 10: Optimized Blocks
2.6 Optimized blocks Optimized blocks S7-1200/1500 controllers have optimized data storage. In optimized blocks, all tags are automatically sorted by their data type. The sorting ensures that data gaps between the tags are minimized and that the tags are stored access-optimized for the processor.
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Page 11: S7-1500: Setup Of Optimized Blocks
S7-1500 can directly read or write all tags with just one machine command). Boolean tags are stored as byte for faster access. The controller therefore does not have to mask the access. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 12: Best Possible Data Storage In The Processor On S7-1500
When accessing, the controller does not The complete byte is blocked for any have to mask the byte. other access. Maximum block size is 64kB. Maximum block size can be up to 16MB. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 13
Example: Setting optimized block access The optimized block accesses for all newly created blocks for S7-1200/1500 is enabled by default. Block access can be set for OBs, FBs and global DBs. For instance DBs, the setting depends on the respective FB. -
Page 14
No “offset” is displayed. displayed and can be used for addressing. In optimized blocks every tag can be In non-optimized blocks only all or no tags declared with “Retain”. can be declared with “Retain”. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 15: Conversion Between Optimized And Non-Optimized Tags
In the case of type-identical allocations between two tags with different storage locations, the system converts automatically. In the case of structured tags, this conversion requires performance and should therefore be avoided, if possible. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 16: Communication With Optimized Data
Any tags or data blocks (derived from PLC data types) can be used as data records. Note It is also possible that the send and receive data are not defined identically: Send data Receive data optimized —> not optimized not optimized —> optimized Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 17: Block Sizes
Data volumes of > 64 kB can be stored in an optimized DB (max. size 16 MB) with S7-1500 controllers. New data types for S7-1200/1500 S7-1200/1500 controllers support new data types in order to make programming more convenient. With the new 64 bit data types considerably larger and more accurate values can be used.
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Page 18: Date_Time_Long Data Type
2 S7-1200/1500 Innovations 2.8 New data types for S7-1200/1500 Table 2-9: Floating-point decimal data types Type Size Value range Real 32 bit (1 bit signs, 8 bit exponent, 23 bit mantissa), -3.40e+38 .. 3.40e+38 accurate to 7 decimal places LReal 64 bit (1 bit signs, 11 bit exponent, 52 bit -1.79e+308 ..
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Page 19
2 S7-1200/1500 Innovations 2.8 New data types for S7-1200/1500 Figure 2-12: VARIANT data type as input parameter for the TSEND_C instruction VARIANT In this case includes the check of the structure TCON_IP_v4 Advantages Integrated type test Symbolic addressing for optimized blocks Recommendation Use the VARIANT data type instead of the ANY pointer. -
Page 20: Instructions
Always use the CALCULATE instruction for mathematical calculations instead of many calls of instructions, such as, e.g. ADD, SUB, etc. 2.9.2 MOVE instructions STEP 7 (TIA) provides the following MOVE instructions. The instruction MOVE_BLK_VARIANT for S7-1200/1500 is new. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 21: Runtime
SCL (S7-1200/S7-1500) and in STL (S7-1500). NOTE You will find further information in the following entry: With S7-1200/S7-1500, how do you measure the time of a program section or the complete program cycle at runtime? http://support.automation.siemens.com/WW/view/en/87668318 Programming Guideline for S7-1200/1500…
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Page 22: Symbolic And Comments
4. Network title comment 5. Network comment 6. Comment on instructions, blocks and functions (open, close, etc.) In the programming languages SCL and STL, it can be commented with // in every row. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 23: System Constants
For S7-300/400 controllers the identification of hardware and software components is performed by logic address or diagnostic addresses. For S7-1200/1500 the identification is by system constants. All hardware and software components (e.g. interfaces, modules, OBs, …) of the S7-1200/1500 controllers have their own system constants. The system constants are automatically created during the setup of the device configuration for the central and distributed I/O.
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Page 24: Internal Reference Id For Controller And Hmi Tags
In the user program “Robot_arm_left” is interconnected with the “GET_DIAG” diagnostic block. Note You will find further information in the following entry: What meaning do the system constants have for the S7-1200/1500 in STEP 7 (TIA Portal)? http://support.automation.siemens.com/WW/view/en/78782836 2.12 Internal reference ID for controller and HMI tags STEP 7, WinCC, Startdrive, Safety and others integrate into the joint data base of the TIA Portal engineering framework.
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Page 25: Stop Mode In The Event Of Errors
TIA Portal. This approach makes the S7-1200/1500 controllers more fault tolerant to errors than their predecessors. Advantages There are only three fault situations that put the S7-1200/1500 controllers into the STOP mode. This makes the programming of the error management clearer and easier.
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Page 26
For S7-1200/1500 controllers there are other programmable error OBs (diagnostic error, module rack failure, etc.). More information on error responses of S7-1200/1500 can be found in the online help of the TIA Portal under “Events and OBs”. Programming Guideline for S7-1200/1500… -
Page 27: General Programming
Due to a good and structured program you get many function units that can be multiply reused within a project and also in other projects. These function units then usually only differ by a different configuration (see chapter 3.2.8 Reusability of blocks). Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 28: Organization Blocks (Ob)
OBs are the interface between the operating system and the user program. They are called by the operating system and control, e.g. the following processes: Startup behavior of the controller Cyclic program processing Interrupt-controlled program processing Error handling Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 29
OBs, use the global DBs (see chapter 4.2 No bit memory but global data blocks). Divide all program parts that belong to each other into folders and store them for reusability in the project or global library. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 30: Functions (Fc)
FCs are blocks without cyclic data storages. This is why the values of block parameters cannot be saved until the next call and has to be provided with actual parameters when called. Properties FCs are blocks without cyclic data storages. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 31
Temporary and out tags are undefined when called in non-optimized blocks. In optimized blocks, the values are always preset to the default value (S7-1500 and S7-1200 Firmware V4). Thus, the resulting behavior is not accidental but reproducible. In order to permanently save the data of an FC, the functions of the global data blocks are available. -
Page 32: Function Blocks (Fb)
Temporary and out tags are undefined when called in non-optimized blocks. In optimized blocks, the values are always preset to the default value (S7-1500 and S7-1200 Firmware V4). Thus, the resulting behavior is not accidental but reproducible. Static tags keep the value from cycle to cycle…
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Page 33: Instances
The following figure shows an FB that uses another FB (“IEC Timer”). All data is saved in a multi instance DB. It is thus possible to create a block with an independent time behavior, for example, a clock generator. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 34
If you require the time and counter function, use the “IEC Timer” blocks and the “IEC Counter” blocks instead of the absolutely addressed SIMATIC Timer. If possible, also always use multi-instances here. This keeps the number of blocks in the user program low. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 35: Global Data Blocks (Db)
How do you declare the timers and counters for the S7-1500 in STEP 7 (TIA Portal) V12? http://support.automation.siemens.com/WW/view/en/67585220 3.2.6 Global data blocks (DB) Figure 3-11: “Add new block” dialog (DB Variable data is located in data blocks that are available to the entire user program. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 36: Downloading Without Reinitialization
3.2.7 Downloading without reinitialization In order to change user programs that already run in a controller, S7-1200 (firmware V4.0) and S7-1500 controllers offer the option to expand the interfaces of optimized function or data blocks during operation. You can load the changed blocks without setting the controller to STOP and without influencing the actual values of already loaded tags.
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Page 37
Define a memory reserve for blocks that are to be expanded during commissioning (e.g. test blocks). The commissioning process is not interrupted by download of new defined tags. The current values of already existing variables are kept. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 38
You can also set a default value for the size of the memory reserve for new blocks in the TIA portal. In the menu bar, navigate to «Options – Settings» and then to «PLC programming – General – Download without reinitialization“. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 39: Reusability Of Blocks
The block concept offers you a number of options to program in a structured and effective way. Advantages Blocks can be used universally in any location of the user program. Blocks can be used universally in different projects. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 40: Block Interface Types
Call-by-value with In interface type When calling the block, the value of the actual parameter is copied onto the input parameter of the block for the In interface type. For this, additional memory is required. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 41: Call-By-Reference With Inout Interface Type
3.4.1 Block interfaces as data exchange If you are encapsulating the functions and program the data exchange between the blocks only via the interfaces, you will clearly have advantages. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 42: Global Memory
This is why you should use global DBs instead of hardware-dependent memory areas. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 43: Local Memory
Note Optimized blocks: Temporary tags are initialized in any block call with the “default value” (S7-1500 und S7-1200 Firmware V4). Non-optimized blocks: Temporary tags are undefined for each call of the block. Programming Guideline for S7-1200/1500…
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Page 44: Access Speed Of Memory Areas
Access to non-optimized Access to optimized DBs blocks Fastest accesses in the S7-1200/1500 in descending order 1. Optimized blocks: Temporary tags, parameters of an FC and FB, non-retentive static tags 2. Optimized blocks whose accesses for compiling are known: –…
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Page 45: Retentivity
CPU 1511-1 PN 88 Kbytes CPU 1513-1 PN 88 Kbytes CPU 1516-3 PN/DP 472 Kbytes Table 3-6: Differences of S7-1200 and S7-1500 S7-1200 S7-1500 Retentivity can only be set for bit memory Retentivity can be set for bit memory, times and counters…
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Page 46
Retentivity can be set from address 0 onward! e.g. from MB0, T0 or C0 Example: Retentive counter You can also declare instances of functions (timer, counter, etc.) retentive. As already described in chapter 3.2.5 Multi-instances Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 47: Symbolic Addressing
If the retentive memory on the PLC is not sufficient, it is possible to store data in the form of data blocks that are only located in the load memory of the PLC. The following entry is described by taking the example of an S7-1200. This programming also works for S7-1500.
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Page 48
Open the program editor and open any block. Enter a symbolic name directly at the input of an instruction. Right-click next to the block and select “Define tag…” in the context menu. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 49: Array Data Type And Indirect Field Accesses
Figure 3-25: ARRAY with 10 elements of the Integer (INT) data type You can indirectly access individual elements in the ARRAY with a runtime tag (array [“index”]). Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 50
Use the “GET_ERR_ID” instruction to catch access errors within the Array. Note You will find further information in the following entry: How do you implement an array access with an S7-1500 with variable index? http://support.automation.siemens.com/WW/view/en/67598676 Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 51: Struct Data Type And Plc Data Types
PLC data type can be used for any number of DBs. You can easily and conveniently create as many DBs of the same structure and adjust them centrally on the PLC data type. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 52: Access To I/O Areas With Plc Data Types
(%Ix.0 or %Qx.0, e.g., %I0.0, %Q12.0, …) 3. Transfer of the PLC tag as actual parameter to the function block 4. Input of the function block is of the type of the created PLC data type Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 53: Slice Access
3.6.5 Slice access For S7-1200/1500 controllers, you can access the memory area of tags of the Byte, Word, DWord or LWord data type. The division of a memory area (e.g. byte or word) into a smaller memory area (e.g. Bool) is also called slice. In the figure below displays the symbolic bit, byte and word accesses to the operands.
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Page 54: Libraries
3.7.1 Types of libraries and library elements Generally there are two different types of libraries: «Project library» «Global library». The content consists of two storage types each: «Types» «Master Copies» Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 55
Subordinate elements are automatically typified. – Types are versioned: Changes can be made by creating a newer version. – There can only be one version of a used type within a controller. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 56: Type Concept
Control elements are edited in a test HMI images and HMI scripts are edited in a environment. test environment. Faceplates and HMI — UDTs are directly edited in the library without test environment. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 57: Versioning Of A Block
Define an input tag of the data type you have created. The PLC data type is therefore subordinate to the function block. Drag the function block via drag & drop into the “Types” folder in the project library. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 58
The subordinate PLC data type is automatically also stored in the library. Example: Changing a type Table 3-10: Changing a type Step Instruction Right-click the block in the “Project library” and select “Edit type” Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 59
In this place you have the option to test the change on the block by loading the project onto a controller. When you have finished testing the block, continue with the following steps. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 60
“Update instances in the project”. If older versions of the element are no longer required you can delete them by clicking “Delete unused type versions from library” Close the library view with “Close library view” Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 61: Process Interrupts
In the following figure you can see the configuration of a “hardware interrupt” in the hardware configuration of a digital input module. Figure 3-34: Configuring hardware interrupt Advantages Fast system response to events (rising, falling edge, etc.) Each event can start a separate OB. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 62
The input delay is used for filtering the input signal in order to, for example, compensate faults such as contact bounce or chatter. Figure 3-35: Setting input delay Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 63: Other Performance Recommendations
Here you can find some general recommendations that enable faster program processing of the controller. Recommendation Note the following recommendations for programming S7-1200/1500 controllers in order to achieve a high performance: LAD/FBD: Disable “generate ENO” for blocks. This avoids tests at runtime.
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Page 64: Scl Programming Language: Tips And Tricks
Call Template mode. The editor expands the call again. You can navigate with the “TAB” button through the parameters. Note: In the “Call Template” mode the writing is in italics. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 65: What Instruction Parameters Are Mandatory
Drag the tag via drag & drop to the tag in the program that is to be replaced. Hold the tag for more than 1 second before releasing it. > hold for 1 second The complete tag is replaced. Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 66: Efficiently Inserting Case Instruction
The compiler can optimize the program better, since it does not know the number of iterations. Example FOR #var := #lower TO #upper DO #var := #var + 1; // no effect, Compiler -> Warning END_FOR; Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 67: For Loop Backwards
This approach is called “overload of operands”. The SCL compiler automatically uses the suitable functions. You can use a reasonable arithmetic for the time types and can therefore program more efficiently. Example TimeDifference := TimeStamp_1 – TimeStamp_2; Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 68
– dtl T_DIFF DTL dt – dt T_DIFF DT date – date T_DIFF DATE ltod – ltod T_DIFF LTOD date + ltod T_COMBINE DATE / LTOD date + tod T_COMBINE DATE / TOD Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674… -
Page 69: Hardware-Independent Programming
4 Hardware-Independent Programming 4.1 Data types of S7-300/400 and S7-1200/1500 Hardware-Independent Programming To make sure that a block can be used on all controllers without any further adjustments, it is important not use hardware-dependent functions and properties. Data types of S7-300/400 and S7-1200/1500 Below is a list of all elementary data types and data groups.
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Page 70: No Bit Memory But Global Data Blocks
VOID PLC data types PLC Data Type For optimized accesses, only symbolic addressing is possible For S7-1200/1500 the TIMER and COUNTER data type is represented by IEC_TIMER and IEC_Counter. No bit memory but global data blocks Advantages Optimized global DBs are clearly more powerful than the bit memory address area that is not optimized for reasons of compatibility.
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Page 71: Programming Of «Clock Bits
If the desired frequency is smaller or equal 0.0, then the output Q = FALSE and Countdown = 0.0. Q [Bool] TRUE Period: 2 seconds Frequency [Real] Countdown [Time] T#0S_703MS Note The complete programming example is available for free download in the following entry: http://support.automation.siemens.com/WW/view/en/87507915 Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 72: The Most Important Recommendations
Chapter 3.6.3 STRUCT data type and PLC data types Using libraries for storing program elements – Chapter 3.7 Libraries No memory bits but global data blocks – Chapter 4.2 No bit memory but global data blocks Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 73: Related Literature
STEP 7 (TIA Portal) manuals http://support.automation.siemens.com/WW /view/en/29156492/133300 S7-1200 Manuals http://support.automation.siemens.com/WW /view/en/34612486/133300 S7-1500 Manuals http://support.automation.siemens.com/WW /view/en/56926743/133300 S7-1200 Getting Started http://support.automation.siemens.com/WW /view/en/39644875 S7-1500 Getting Started http://support.automation.siemens.com/WW /view/en/78027451 SIMATIC S7-1200 / S7-1500 http://support.automation.siemens.com/WW Comparison list for programming /view/en/86630375 languages Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
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Page 74: History
Extension of following chapter: 2.2 Terms 2.3 Programming languages 2.6 Optimized blocks 2.8.2 Date_Time_Long data type 2.10 Symbolic and comments 3.2 Program blocks 3.5 Retentivity 4.3 Programming of «clock bits» Several corrections in different chapter Programming Guideline for S7-1200/1500 V1.2, Entry ID: 81318674…
This manual is also suitable for:
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Основные функции аппаратного и программного обеспечения S7–300.
Система автоматизации S7-300 Данные модулей
Общие технические данные. Источники питания. Цифровые модули. Принципы обработки аналоговых величин. Представление аналоговых величин аналоговых модулей. Аналоговые модули. Другие сигнальные модули. Интерфейсные модули. Повторитель RS 485. Наборы параметров сигнальных модулей. Диагностические данные сигнальных модулей
S7-300 CPU 31xC и CPU 31x, технические данные
Путеводитель по документации S7-300. Элементы управления и индикации. Обмен данными. Концепция памяти. Времена цикла и реакции. Общие технические данные. Технические данные CPU 31xC. Технические данные CPU31x 8.
SIMATIC S5-90U, S5-95U, S5-95F, S5-100U
Программируемый контроллер S5-95U
SIMATIC S5. Контроллер S5-100U (CPU100/CPU102). Руководство по применению.
SIMATIC S5. Контроллер SIMATIC S5-115U
Программируемые контроллеры S7-200
SIMATIC S7–200. Обзор продукта.
SIMATIC S7-300. Общие сведения. Ч1.
SIMATIC S7-300. Функциональные модули. Ч2.
S7-400. Система автоматизации S7-400. Данные CPU.
Программируемые контроллеры S7-400. Обзор.
SIMATIC S7-1200 -микроконтроллер для Totally Integrated Automation
SIMATIC S7-1500 контроллер для Totally Integrated Automation
LOGO! Руководство.
Логические модули LOGO!
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Введение в STEP 7. Руководство.
Программирование с помощью STEP 7 V5.3
SIMATIC NET NCM S7 для PROFIBUS CP
SIMATIC NET NCM S7 для Industrial Ethernet
Конфигурирование аппаратуры и коммуникационных соединений STEP 7 V5.3
Первые шаги в PLC S7-200
Программируемый контроллер S7-200 Руководство по эксплуатации
CP 243-1 Коммуникационный процессор для Industrial Ethernet
Первые шаги в PLC S7-300
Система автоматизации S7-300 Данные модулей
S7-300 CPU 31xC и CPU 31x, технические данные
SIMATIC S5-90U, S5-95U, S5-95F, S5-100U
Программируемый контроллер S5-95U
SIMATIC S5. Контроллер S5-100U (CPU100/CPU102). Руководство по применению.
SIMATIC S5. Контроллер SIMATIC S5-115U
Программируемые контроллеры S7-200
SIMATIC S7–200. Обзор продукта.
SIMATIC S7-300. Общие сведения. Ч1.
S7-400. SIMATIC S7-300. Функциональные модули. Ч2.
S7-400. Система автоматизации S7-400. Данные CPU.
Программируемые контроллеры S7-400. Обзор.
SIMATIC S7-1200 -микроконтроллер для Totally Integrated Automation
SIMATIC S7-1500 -микроконтроллер для Totally Integrated Automation
LOGO! Руководство.
Логические модули LOGO!
Программное обеспечение
S7-300 Документация. Данные модулей.
1_General_r.pdf
2_PowerSupply_r.pdf
3_Digital_r_MN.pdf
4_Analog_r_MN.pdf
5_OtherSignalModules_r.pdf
6_InterfaceModules_r.pdf
7_Repeater_r_MN.pdf
8_SIMATIC_TOP_r.pdf
GS_SM331_4-20mA_r.pdf
GS_SM331_TC_r.pdf
GS_SM331_U&PT100_r.pdf
S7-300 Документация. Данные ЦПУ.
CPU_31xC_&_CPU_31x_r.pdf
S7-300 Документация. Модуль автоматическогого регулирования FM355.
00_Preface&Contents_r_355.pdf
01_Overview_r_355.pdf
02_Settings_r.pdf
03_Work_r.pdf
04_Installing_r.pdf
05_Wiring_r.pdf
06_Assign_Parameters_r.pdf
07_User_Programm_r.pdf
08_StartingUp_r_355.pdf
09_Properties_DIO-AIO_r.pdf
10_Connecting_r.pdf
11_Assignment_DB_r.pdf
12_Faults&Diagnostics_r.pdf
13_Examples_r.pdf
Appendix_r_355.pdf
S7-300 Документация. Первые шаги.
GS_Analog_r.pdf
GS_Controlling_r.pdf
GS_Counting_r.pdf
GS_Digital_r.pdf
GS_PtP_r.pdf
S7-300 Документация. Первые шаги в пуско-наладочных работах для FM355.
get_c_r.pdf
get_s_r.pdf
S7-300 Документация. Примеры программ.
S7-300C_TF-Sample_r.pdf
S7-300 Документация Система S7-300.Руководство по инсталяции
0_Titelblatt_r.pdf
01-04_Preface_r.pdf
05_Configuring_r.pdf
06-07_Installation_r.pdf
08-09_Addressing_r.pdf
10-11_Maintenance_r.pdf
12-13-ind_Appendix_r.pdf
S7-300 Документация. Список инструкций системы S7-300.
OpList_S7-300C_r.pdf
S7-300 Документация. Технологические функции CPU 31xC.
0_Preface_Contents_r_TF.pdf
1_Overview_r.pdf
2_Positioning_r.pdf
3_Positioning_AO_r.pdf
4_Positioning_DO_r.pdf
6_Point-to-Point_r.pdf
7_Controlling_r.pdf
S7-300 Документация. Функциональный модуль FM350-1.
01_ProductOverview_r.pdf
02_HowCounts_r.pdf
04_Wiring_r.pdf
05_Assigning_Parameters_r.pdf
06_Programming_r.pdf
07_Programming_in_M7_r.pdf
08_StartingUp_r_350.pdf
09_OperatingModes_r.pdf
10_EncoderSignals_r.pdf
11_DB_Assignments_r.pdf
12_M7_Function_Library_r.pdf
13_Faults&Diagnostics_r.pdf
A_Appendix_r_350.pdf
GetStarted_FM350-1_r.pdf
S7-200 Документация S7-200 Примеры применения
Contents_r.pdf
ContentsSort_e.pdf
S72_01.pdf
S72_02.pdf
S72_03.pdf
S72_04.pdf
S72_05.pdf
S72_06.pdf
S72_07.pdf
S72_08.pdf
S72_09.pdf
S72_10.pdf
S72_11.pdf
S72_12.pdf
S72_13.pdf
S72_14.pdf
S72_15.pdf
S72_16.pdf
S72_17.pdf
S72_18.pdf
S72_19.pdf
S72_20.pdf
S72_21.pdf
S72_22.pdf
S72_23.pdf
S72_24.pdf
S72_25.pdf
S72_26.pdf
S72_27.pdf
S72_28.pdf
S72_29.pdf
S72_30.pdf
S72_31.pdf
S72_32.pdf
S72_33.pdf
S72_34.pdf
S72_35.pdf
S72_36.pdf
S72_37.pdf
S72_38.pdf
S72_39.pdf
S72_40.pdf
S72_41.pdf
S72_42.pdf
S72_43.pdf
S72_44.pdf
S72_45.pdf
S72_46.pdf
S72_47.pdf
S72_48.pdf
S72_49.pdf
S72_50.pdf
S72_51.pdf
S72_52.pdf
S72_53.pdf
S72_54.pdf
S72_55.pdf
S72_56.pdf
S72_57.pdf
Интерфейс оператора TD 200
01_Overview&Installation_r.pdf
02_Configuring_r.pdf
03_Operating_r.pdf
04_Creating_programs_r.pdf
A_Appendix_r_TD200.pdf
Titel_r.pdf
Коммуникационный модуль CP243-1
CP243-1_1ru.pdf
Коммуникационный процессор CP 243-1 IT
CP243-1it_E.pdf
Первые шаги
1steps_r.pdf
Сенсорная панель TPO70
05_TP070_r.pdf
Системное руководство СРU21x
0_Preface_r.pdf
1_Introducing_r.pdf
2_Installing_HW_r.pdf
3_Installing_SW_r.pdf
4_GettingStarted_r.pdf
5_Programming_r.pdf
6_Memory_r.pdf
7_InputOutput_r.pdf
8_Communication_r.pdf
9_Instruction_r.pdf
A_TechData_r.pdf
B_Appendix_r.pdf
Системное руководство СРU22x
0_preface.pdf
01_Owerview_r.pdf
02_GettingStarted_r.pdf
03_Installing_r.pdf
04_PLC%20Concepts_r.pdf
05_ProgrammingConcepts_r.pdf
06_InstructionSet_r.pdf
07_Communicating_r.pdf
08_TroubleShooting_r.pdf
09_PositionModule_r.pdf
10_ModemModule_r.pdf
11_USS_Protocol_r.pdf
12_ModbusProtocol_r.pdf
A_Appendix_r1.pdf
I_Index_r.pdf»
06_InstructionSet_r.pdf
10_ModemModule_r.pdf
01_Introduction_r.pdf
02_S7-200_r.pdf
03_SIPLUS_r.pdf
A_Appendix_r.pdf