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Last modified by Mora Zhou on 2024/08/08 14:35
From version 11.1
edited by Stone Wu
on 2022/09/21 17:22
Change comment: There is no comment for this version
To version 1.1
edited by Leo Wei
on 2022/06/08 12:57
Change comment: Imported from XAR

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1 -PLC Editor2.WebHome
1 +PLC Editor2.1 User manual.2\.1 LX5V user manual.WebHome
Author
... ... @@ -1,1 +1,1 @@
1 -XWiki.Stone
1 +XWiki.admin
Content
... ... @@ -1,5 +1,7 @@
1 -= {{id name="_Toc23711"/}}**ZRN/DZRN/Origin return** =
1 += **High-speed pulse output instruction** =
2 2  
3 +== {{id name="_Toc23711"/}}**ZRN/DZRN/Origin return** ==
4 +
3 3  **ZRN/DZRN**
4 4  
5 5  This instruction is to use the specified pulse speed and pulse output port to make the actuator move to the origin of action (DOG) when the PLC and the servo drive work together, until the origin signal meets the conditions.
... ... @@ -9,33 +9,33 @@
9 9  **{{id name="OLE_LINK392"/}}Content, range and data type**
10 10  
11 11  (% class="table-bordered" %)
12 -|**Parameter**|(% style="width:392px" %)**Content**|(% style="width:155px" %)**Range**|(% style="width:236px" %)**Data type**|(% style="width:204px" %)**Data type (label)**
13 -|(s1)|(% style="width:392px" %)The speed when the origin return starts|(% style="width:155px" %)(((
14 +|**Parameter**|**Content**|**Range**|**Data type**|**Data type (label)**
15 +|(s1)|The speed when the origin return starts|(((
14 14  1 to 32767
15 15  
16 16  1 to 200000
17 -)))|(% style="width:236px" %)Signed BIN16/Signed BIN32|(% style="width:204px" %)ANY16_S/ANY32_S
18 -|(s2)|(% style="width:392px" %)Crawl speed|(% style="width:155px" %)(((
19 +)))|Signed BIN16/Signed BIN32|ANY16_S/ANY32_S
20 +|(s2)|Crawl speed|(((
19 19  1 to 32767
20 20  
21 21  1 to 200000
22 -)))|(% style="width:236px" %)Signed BIN16/Signed BIN32|(% style="width:204px" %)ANY16_S/ANY32_S
23 -|(s3)|(% style="width:392px" %)The device number of the input number of the near-point signal (DOG) to be input.|(% style="width:155px" %)-|(% style="width:236px" %)Bit|(% style="width:204px" %)ANY_BOOL
24 -|(d)|(% style="width:392px" %)The device number (Y) that outputs pulse|(% style="width:155px" %)-|(% style="width:236px" %)Bit|(% style="width:204px" %)ANY_BOOL
24 +)))|Signed BIN16/Signed BIN32|ANY16_S/ANY32_S
25 +|(s3)|The device number of the input number of the near-point signal (DOG) to be input.|-|Bit|ANY_BOOL
26 +|(d)|The device number (Y) that outputs pulse|-|Bit|ANY_BOOL
25 25  
26 26  **Device used**
27 27  
28 -(% class="table-bordered" style="width:1049px" %)
29 -|(% rowspan="2" %)**Instruction**|(% rowspan="2" style="width:133px" %)**Parameter**|(% colspan="14" style="width:617px" %)**Devices**|(% style="width:138px" %)**Offset modification**|(((
30 +(% class="table-bordered" %)
31 +|(% rowspan="2" %)**Instruction**|(% rowspan="2" %)**Parameter**|(% colspan="14" %)**Devices**|**Offset modification**|(((
30 30  **Pulse**
31 31  
32 32  **extension**
33 33  )))
34 -|(% style="width:3px" %)**X**|**Y**|**M**|**S**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|(% style="width:75px" %)**H**|(% style="width:138px" %)**[D]**|**XXP**
35 -|(% rowspan="4" %)ZRN|(% style="width:133px" %)Parameter 1|(% style="width:3px" %) | | | |●|●|●|●|●|●|●|●|●|(% style="width:75px" %)●|(% style="width:138px" %)●|
36 -|(% style="width:133px" %)Parameter 2|(% style="width:3px" %) | | | |●|●|●|●|●|●|●|●|●|(% style="width:75px" %)●|(% style="width:138px" %)●|
37 -|(% style="width:133px" %)Parameter 3|(% style="width:3px" %)●|●|●|●| | | | | | | | | |(% style="width:75px" %) |(% style="width:138px" %) |
38 -|(% style="width:133px" %)Parameter 4|(% style="width:3px" %) |●| | | | | | | | | | | |(% style="width:75px" %) |(% style="width:138px" %) |
36 +|**X**|**Y**|**M**|**S**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|**H**|**[D]**|**XXP**
37 +|(% rowspan="4" %)ZRN|Parameter 1| | | | |●|●|●|●|●|●|●|●|●|●|●|
38 +|Parameter 2| | | | |●|●|●|●|●|●|●|●|●|●|●|
39 +|Parameter 3|●|●|●|●| | | | | | | | | | | |
40 +|Parameter 4| |●| | | | | | | | | | | | | |
39 39  
40 40  **Features**
41 41  
... ... @@ -44,7 +44,7 @@
44 44  .
45 45  
46 46  (% style="text-align:center" %)
47 -[[image:08_html_abde218848583ae7.gif||height="352" width="700" class="img-thumbnail"]]
49 +[[image:08_html_abde218848583ae7.gif||class="img-thumbnail" height="352" width="700"]]
48 48  
49 49  • Specify the speed at the start of origin return in (s1). (It should be in the range of 1 to 200,000)
50 50  
... ... @@ -59,7 +59,7 @@
59 59  • The pulse frequency could be modified during operation.
60 60  
61 61  (% style="text-align:center" %)
62 -[[image:1652679761818-564.png||height="409" width="800" class="img-thumbnail"]]
64 +[[image:1652679761818-564.png||class="img-thumbnail" height="409" width="800"]]
63 63  
64 64  **{{id name="OLE_LINK84"/}}✎Note:**
65 65  
... ... @@ -70,7 +70,7 @@
70 70  Please set the near-point DOG between the reverse limit 1 (LSR) and the forward limit 1 (LSF). When near-point DOG, reverse limit 1 (LSR), forward limit 1 (LSF) do not form the relationship shown in the figure below, the action may not be performed.
71 71  
72 72  (% style="text-align:center" %)
73 -[[image:08_html_e424715fa5809765.png||height="129" width="800" class="img-thumbnail"]]
75 +[[image:08_html_e424715fa5809765.png||class="img-thumbnail" height="129" width="800"]]
74 74  
75 75  Please make the crawling speed slow enough. Since it does not decelerate to stop, if the crawling speed is too fast, the stop position will shift due to inertia.
76 76  
... ... @@ -85,11 +85,11 @@
85 85  **Example**
86 86  
87 87  (% style="text-align:center" %)
88 -[[image:08_html_5398e9b5857a7283.png||height="366" width="700" class="img-thumbnail"]]
90 +[[image:08_html_5398e9b5857a7283.png||class="img-thumbnail" height="366" width="700"]]
89 89  
90 90  {{id name="OLE_LINK86"/}}Set Y1 as the output axis at a maximum speed of 200K, a offset speed of 500, and a acceleration/deceleration time of 100ms. Origin return is performed at the frequency of 200Khz, and it runs at a crawling speed after receiving the origin signal X0, and it stops after the X0 signal is reset.
91 91  
92 -= {{id name="_Toc17090"/}}**{{id name="_Toc4613"/}}{{id name="_Toc28244"/}}DSZR/DDSZR/Origin return** =
94 +== {{id name="_Toc17090"/}}**{{id name="_Toc4613"/}}{{id name="_Toc28244"/}}DSZR/DDSZR/Origin return** ==
93 93  
94 94  **{{id name="OLE_LINK390"/}}DSZR/DDSZR**
95 95  
... ... @@ -100,35 +100,35 @@
100 100  **Content, range and data type**
101 101  
102 102  (% class="table-bordered" %)
103 -|**Parameter**|(% style="width:457px" %)**Content**|(% style="width:124px" %)**Range**|(% style="width:226px" %)**Data type**|(% style="width:180px" %)**Data type (label)**
104 -|(s1)|(% style="width:457px" %)The speed when the origin return starts|(% style="width:124px" %)(((
105 +|**Parameter**|**Content**|**Range**|**Data type**|**Data type (label)**
106 +|(s1)|The speed when the origin return starts|(((
105 105  1 to 32767
106 106  
107 107  1 to 200000
108 -)))|(% style="width:226px" %)Signed BIN16/Signed BIN32|(% style="width:180px" %)ANY16_S/ANY32_S
109 -|(s2)|(% style="width:457px" %)Crawling speed|(% style="width:124px" %)(((
110 +)))|Signed BIN16/Signed BIN32|ANY16_S/ANY32_S
111 +|(s2)|Crawling speed|(((
110 110  1 to 32767
111 111  
112 112  1 to 200000
113 -)))|(% style="width:226px" %)Signed BIN16/Signed BIN32|(% style="width:180px" %)ANY16_S/ANY32_S
114 -|(s3)|(% style="width:457px" %)The device number of the input number of the near-point signal (DOG) to be input.|(% style="width:124px" %)-|(% style="width:226px" %)Bit|(% style="width:180px" %)ANY_BOOL
115 -|(d1)|(% style="width:457px" %)The device number (Y) that outputs pulse|(% style="width:124px" %)-|(% style="width:226px" %)Bit|(% style="width:180px" %)ANY_BOOL
116 -|(d2)|(% style="width:457px" %){{id name="OLE_LINK393"/}}Operation direction output port or bit variable|(% style="width:124px" %) |(% style="width:226px" %) |(% style="width:180px" %)
115 +)))|Signed BIN16/Signed BIN32|ANY16_S/ANY32_S
116 +|(s3)|The device number of the input number of the near-point signal (DOG) to be input.|-|Bit|ANY_BOOL
117 +|(d1)|The device number (Y) that outputs pulse|-|Bit|ANY_BOOL
118 +|(d2)|{{id name="OLE_LINK393"/}}Operation direction output port or bit variable| | |
117 117  
118 118  **Device used**
119 119  
120 -(% class="table-bordered" style="width:1022px" %)
121 -|(% rowspan="2" %)**Instruction**|(% rowspan="2" style="width:133.641px" %)**Parameter**|(% colspan="15" style="width:630.359px" %)**Devices**|(% style="width:128px" %)**Offset modification**|(((
122 +(% class="table-bordered" %)
123 +|(% rowspan="2" %)**Instruction**|(% rowspan="2" %)**Parameter**|(% colspan="15" %)**Devices**|**Offset modification**|(((
122 122  **Pulse**
123 123  
124 124  **extension**
125 125  )))
126 -|(% style="width:1px" %)**X**|**Y**|**M**|**S**|**D.b**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|(% style="width:76px" %)**H**|(% style="width:128px" %)**[D]**|**XXP**
127 -|(% rowspan="5" %)DSZR|(% style="width:133.641px" %)Parameter 1|(% style="width:1px" %) | | | | |●|●|●|●|●|●|●|●|●|(% style="width:76px" %)●|(% style="width:128px" %)●|
128 -|(% style="width:133.641px" %)Parameter 2|(% style="width:1px" %) | | | | |●|●|●|●|●|●|●|●|●|(% style="width:76px" %)●|(% style="width:128px" %)●|
129 -|(% style="width:133.641px" %)Parameter 3|(% style="width:1px" %)●|●|●|●| | | | | | | | | | |(% style="width:76px" %) |(% style="width:128px" %) |
130 -|(% style="width:133.641px" %)Parameter 4|(% style="width:1px" %) |●| | | | | | | | | | | | |(% style="width:76px" %) |(% style="width:128px" %) |
131 -|(% style="width:133.641px" %)Parameter 5|(% style="width:1px" %) |●|●|●|●| | | | | | | | | |(% style="width:76px" %) |(% style="width:128px" %) |
128 +|**X**|**Y**|**M**|**S**|**D.b**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|**H**|**[D]**|**XXP**
129 +|(% rowspan="5" %)DSZR|Parameter 1| | | | | |●|●|●|●|●|●|●|●|●|●|●|
130 +|Parameter 2| | | | | |●|●|●|●|●|●|●|●|●|●|●|
131 +|Parameter 3|●|●|●|●| | | | | | | | | | | | |
132 +|Parameter 4| |●| | | | | | | | | | | | | | |
133 +|Parameter 5| |●|●|●|●| | | | | | | | | | | |
132 132  
133 133  **Features**
134 134  
... ... @@ -135,7 +135,7 @@
135 135  The instruction is that when the PLC works with the servo drive, it uses the specified pulse speed and pulse output port and the specified direction axis to move the actuator to the origin of the action (DOG) until the origin signal meets the conditions.
136 136  
137 137  (% style="text-align:center" %)
138 -[[image:08_html_abde218848583ae7.gif||height="403" width="800" class="img-thumbnail"]]
140 +[[image:08_html_abde218848583ae7.gif||class="img-thumbnail" height="403" width="800"]]
139 139  
140 140  • Specify the speed at the start of origin return in (s1). (It should be in the range of 1 to 200000)
141 141  
... ... @@ -152,7 +152,7 @@
152 152  • The pulse frequency could be modified during operation.{{id name="OLE_LINK398"/}}
153 153  
154 154  (% style="text-align:center" %)
155 -[[image:1652679890567-504.png||height="406" width="800" class="img-thumbnail"]]
157 +[[image:1652679890567-504.png||class="img-thumbnail" height="406" width="800"]]
156 156  
157 157  **✎Note:**
158 158  
... ... @@ -165,7 +165,7 @@
165 165  {{id name="OLE_LINK399"/}}
166 166  
167 167  (% style="text-align:center" %)
168 -[[image:08_html_3152d1fc65e8de15.gif||height="128" width="900" class="img-thumbnail"]]
170 +[[image:08_html_3152d1fc65e8de15.gif||class="img-thumbnail" height="128" width="900"]]
169 169  
170 170   Please make the crawling speed slow enough. Since it does not decelerate to stop, if the crawling speed is too fast, the stop position will shift due to inertia.
171 171  
... ... @@ -184,7 +184,7 @@
184 184  
185 185  Set Y1 as the output axis and Y10 as the direction axis at a maximum speed of 200K, a offset speed of 500, and a acceleration/deceleration time of 100ms. Origin return is performed at the frequency of 200Khz, and it runs at a crawling speed after receiving the origin signal X0, and it stops after the X0 signal is reset.
186 186  
187 -= **{{id name="_Toc4674"/}}DVIT/DDVIT/16-bit data relative positioning** =
189 +== **{{id name="_Toc4674"/}}DVIT/DDVIT/16-bit data relative positioning** ==
188 188  
189 189  **DVIT/DDVIT**
190 190  
... ... @@ -221,17 +221,17 @@
221 221  **Device used**
222 222  
223 223  (% class="table-bordered" %)
224 -|(% rowspan="2" %)**Instruction**|(% rowspan="2" style="width:134.641px" %)**Parameter**|(% colspan="15" style="width:628.359px" %)**Devices**|(% style="width:129px" %)**Offset modification**|(((
226 +|(% rowspan="2" %)**Instruction**|(% rowspan="2" %)**Parameter**|(% colspan="15" %)**Devices**|**Offset modification**|(((
225 225  **Pulse**
226 226  
227 227  **extension**
228 228  )))
229 -|(% style="width:1px" %)**X**|**Y**|**M**|**S**|**D.b**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|(% style="width:75px" %)**H**|(% style="width:129px" %)**[D]**|**XXP**
230 -|(% rowspan="5" %)DVIT|(% style="width:134.641px" %)Parameter 1|(% style="width:1px" %) | | | | |●|●|●|●|●|●|●|●|●|(% style="width:75px" %)●|(% style="width:129px" %)●|
231 -|(% style="width:134.641px" %)Parameter 2|(% style="width:1px" %) | | | | |●|●|●|●|●|●|●|●|●|(% style="width:75px" %)●|(% style="width:129px" %)●|
232 -|(% style="width:134.641px" %)Parameter 3|(% style="width:1px" %) |●| | | | | | | | | | | | |(% style="width:75px" %) |(% style="width:129px" %) |
233 -|(% style="width:134.641px" %)Parameter 4|(% style="width:1px" %) |●|●|●|●| | | | | | | | | |(% style="width:75px" %) |(% style="width:129px" %) |
234 -|(% style="width:134.641px" %)Parameter 5|(% style="width:1px" %)●| |●|●| | | | | | | | | | |(% style="width:75px" %) |(% style="width:129px" %) |
231 +|**X**|**Y**|**M**|**S**|**D.b**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|**H**|**[D]**|**XXP**
232 +|(% rowspan="5" %)DVIT|Parameter 1| | | | | |●|●|●|●|●|●|●|●|●|●|●|
233 +|Parameter 2| | | | | |●|●|●|●|●|●|●|●|●|●|●|
234 +|Parameter 3| |●| | | | | | | | | | | | | | |
235 +|Parameter 4| |●|●|●|●| | | | | | | | | | | |
236 +|Parameter 5|●| |●|●| | | | | | | | | | | | |
235 235  
236 236  **Features**
237 237  
... ... @@ -248,7 +248,7 @@
248 248  • Specify the bit device of the interrupt signal in (d3). Only the devices and general outputs specified in the parameters could be specified.
249 249  
250 250  (% style="text-align:center" %)
251 -[[image:08_html_5f96163eb153efdb.gif||height="428" width="800" class="img-thumbnail"]]
253 +[[image:08_html_5f96163eb153efdb.gif||class="img-thumbnail" height="428" width="800"]]
252 252  
253 253  **✎Note:**
254 254  
... ... @@ -278,9 +278,9 @@
278 278  Set Y0 as the output axis and Y1 as the direction axis with the maximum speed of 200K, the offset speed of 500, and the acceleration/deceleration time of 100ms, and run at a frequency of 200,000, and send 200,000 pulses after receiving the X0 signal.
279 279  
280 280  (% style="text-align:center" %)
281 -[[image:08_html_cbfdbddb08628e8c.gif||height="419" width="800" class="img-thumbnail"]]
283 +[[image:08_html_cbfdbddb08628e8c.gif||class="img-thumbnail" height="419" width="800"]]
282 282  
283 -= {{id name="_Toc22468"/}}**DRVI/DDRVI/Relative positioning** =
285 +== {{id name="_Toc22468"/}}**DRVI/DDRVI/Relative positioning** ==
284 284  
285 285  **DRVI/DDRVI**
286 286  
... ... @@ -331,17 +331,17 @@
331 331  
332 332  **Device used**
333 333  
334 -(% class="table-bordered" style="width:1046px" %)
335 -|(% rowspan="2" %)**Instruction**|(% rowspan="2" style="width:132.875px" %)**Parameter**|(% colspan="14" style="width:603.125px" %)**Devices**|(% style="width:125px" %)**Offset modification**|(((
336 +(% class="table-bordered" %)
337 +|(% rowspan="2" %)**Instruction**|(% rowspan="2" %)**Parameter**|(% colspan="14" %)**Devices**|**Offset modification**|(((
336 336  **Pulse**
337 337  
338 338  **extension**
339 339  )))
340 -|(% style="width:1px" %)**Y**|**M**|**S**|**D.b**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|(% style="width:79px" %)**H**|(% style="width:125px" %)**[D]**|**XXP**
341 -|(% rowspan="4" %)DRVI|(% style="width:132.875px" %)Parameter 1|(% style="width:1px" %) | | | |●|●|●|●|●|●|●|●|●|(% style="width:79px" %)●|(% style="width:125px" %)●|
342 -|(% style="width:132.875px" %)Parameter 2|(% style="width:1px" %) | | | |●|●|●|●|●|●|●|●|●|(% style="width:79px" %)●|(% style="width:125px" %)●|
343 -|(% style="width:132.875px" %)Parameter 3|(% style="width:1px" %)●| | | | | | | | | | | | |(% style="width:79px" %) |(% style="width:125px" %) |
344 -|(% style="width:132.875px" %)Parameter 4|(% style="width:1px" %)●|●|●|●| | | | | | | | | |(% style="width:79px" %) |(% style="width:125px" %) |
342 +|**Y**|**M**|**S**|**D.b**|**KnX**|**KnY**|**KnM**|**KnS**|**T**|**C**|**D**|**R**|**K**|**H**|**[D]**|**XXP**
343 +|(% rowspan="4" %)DRVI|Parameter 1| | | | |●|●|●|●|●|●|●|●|●|●|●|
344 +|Parameter 2| | | | |●|●|●|●|●|●|●|●|●|●|●|
345 +|Parameter 3|●| | | | | | | | | | | | | | |
346 +|Parameter 4|●|●|●|●| | | | | | | | | | | |
345 345  
346 346  **Features**
347 347  
... ... @@ -350,7 +350,7 @@
350 350  With the current stop position as the starting point, specify the movement direction and movement amount (relative address) for positioning.
351 351  
352 352  (% style="text-align:center" %)
353 -[[image:08_html_9e2927d44c64e0be.gif||height="323" width="800" class="img-thumbnail"]]
355 +[[image:08_html_9e2927d44c64e0be.gif||class="img-thumbnail" height="323" width="800"]]
354 354  
355 355  • Specify the positioning address of the user unit with a relative address in (s1). (It should be in the range of -2147483647 to +2147483647)
356 356  
... ... @@ -363,7 +363,7 @@
363 363  • The pulse frequency and pulse position could be modified during the operation of this instruction.
364 364  
365 365  (% style="text-align:center" %)
366 -[[image:08_html_50efa4160b140701.gif||height="418" width="800" class="img-thumbnail"]]
368 +[[image:08_html_50efa4160b140701.gif||class="img-thumbnail" height="418" width="800"]]
367 367  
368 368  **✎Note:**
369 369  
... ... @@ -384,7 +384,7 @@
384 384  
385 385  {{id name="OLE_LINK91"/}}{{id name="OLE_LINK92"/}}Set Y0 as the output axis, and Y1 as the direction axis with the maximum speed in 200K, and the offset speed in 500, and the acceleration/deceleration time in 100ms. Send a high-speed pulse with acceleration and deceleration at a frequency of 200KHZ, and a pulse number of 200K.
386 386  
387 -= {{id name="_Toc23478"/}}**{{id name="_Toc19438"/}}{{id name="_Toc5660"/}}DRVA/DDRVA/Absolute positioning** =
389 +== {{id name="_Toc23478"/}}**{{id name="_Toc19438"/}}{{id name="_Toc5660"/}}DRVA/DDRVA/Absolute positioning** ==
388 388  
389 389  **DRVA/DDRVA**
390 390  
... ... @@ -450,7 +450,7 @@
450 450  {{id name="OLE_LINK365"/}}
451 451  
452 452  (% style="text-align:center" %)
453 -[[image:08_html_7a3c30baa77024fb.gif||height="311" width="800" class="img-thumbnail"]]
455 +[[image:08_html_7a3c30baa77024fb.gif||class="img-thumbnail" height="311" width="800"]]
454 454  
455 455  • Specify the positioning address of user unit with a absolute address in (s1). (It should be in the range of -2,147,483,647 to +2,147,483,647)
456 456  
... ... @@ -463,7 +463,7 @@
463 463  • The pulse frequency and pulse position could be modified during the operation of this instruction.
464 464  
465 465  (% style="text-align:center" %)
466 -[[image:08_html_620f348d2565adf2.gif||height="411" width="800" class="img-thumbnail"]]
468 +[[image:08_html_620f348d2565adf2.gif||class="img-thumbnail" height="411" width="800"]]
467 467  
468 468  **✎Note:**
469 469  
... ... @@ -484,7 +484,7 @@
484 484  
485 485  Set Y0 as the output axis, and Y1 as the direction axis with the maximum speed in 200K, and the offset speed in 500, and the acceleration/deceleration time in 100ms. Send a high-speed pulse with acceleration and deceleration at a frequency of 200KHZ, starting at the origin position and ending at 200,000
486 486  
487 -= {{id name="_Toc21291"/}}**{{id name="_Toc21950"/}}{{id name="_Toc10018"/}}PLSR/DPLSR/Pulse output with acceleration and deceleration** =
489 +== {{id name="_Toc21291"/}}**{{id name="_Toc21950"/}}{{id name="_Toc10018"/}}PLSR/DPLSR/Pulse output with acceleration and deceleration** ==
488 488  
489 489  **PLSR/DPLSR**
490 490  
... ... @@ -564,7 +564,7 @@
564 564  • Specify the device that outputs pulses in (d). Only output devices (Y) with positioning parameters could be specified.
565 565  
566 566  (% style="text-align:center" %)
567 -[[image:08_html_1b0fa8d702052193.gif||height="382" width="700" class="img-thumbnail"]]
569 +[[image:08_html_1b0fa8d702052193.gif||class="img-thumbnail" height="382" width="700"]]
568 568  
569 569  **✎Note:**
570 570  
... ... @@ -585,7 +585,7 @@
585 585  
586 586  Set Y0 as the output axis at a maximum speed of 200K, and a offset speed of 500, and a acceleration/deceleration time of 100ms. Send a high-speed pulse with acceleration and deceleration at a frequency of 200KHZ, a pulse number of 200K.
587 587  
588 -= {{id name="_Toc10313"/}}**{{id name="_Toc31417"/}}{{id name="_Toc9007"/}}PLSR2/Multi-speed positioning** =
590 +== {{id name="_Toc10313"/}}**{{id name="_Toc31417"/}}{{id name="_Toc9007"/}}PLSR2/Multi-speed positioning** ==
589 589  
590 590  **PLSR2**
591 591  
... ... @@ -738,7 +738,7 @@
738 738  The waveform diagram is as follows:
739 739  
740 740  (% style="text-align:center" %)
741 -[[image:08_html_3117922fe2a20cac.gif||height="387" width="700" class="img-thumbnail"]]
743 +[[image:08_html_3117922fe2a20cac.gif||class="img-thumbnail" height="387" width="700"]]
742 742  
743 743  2) Waiting time
744 744  
... ... @@ -762,7 +762,7 @@
762 762  The waveform diagram is as follows:
763 763  
764 764  (% style="text-align:center" %)
765 -[[image:08_html_6bc1d175fa4748a6.gif||height="372" width="700" class="img-thumbnail"]]
767 +[[image:08_html_6bc1d175fa4748a6.gif||class="img-thumbnail" height="372" width="700"]]
766 766  
767 767  3) Waiting signal
768 768  
... ... @@ -786,7 +786,7 @@
786 786  If the signal is received in advance, it will not decelerate to stop, but directly accelerate/decelerate to the specified speed of the next segment. (X2 low level is received during operation)
787 787  
788 788  (% style="text-align:center" %)
789 -[[image:08_html_5599da81e80c2958.gif||height="413" width="700" class="img-thumbnail"]]
791 +[[image:08_html_5599da81e80c2958.gif||class="img-thumbnail" height="413" width="700"]]
790 790  
791 791  4)** **Trigger signal
792 792  
... ... @@ -812,7 +812,7 @@
812 812  The pulse waveform diagram is as follows:
813 813  
814 814  (% style="text-align:center" %)
815 -[[image:08_html_a84e97c5590c3f71.gif||height="371" width="700" class="img-thumbnail"]]
817 +[[image:08_html_a84e97c5590c3f71.gif||class="img-thumbnail" height="371" width="700"]]
816 816  
817 817  If a signal is received in the acceleration section (deceleration section), it will directly accelerate (decelerate) in the current section to the next pulse frequency.
818 818  
... ... @@ -826,7 +826,7 @@
826 826  |(% style="width:127px" %)4085H|(% style="width:954px" %)The table parameter with the first address in the read application instruction (s) exceeds the device range, and the output result of the read parameter (s), (d1) and (d2) exceeds the device range
827 827  |(% style="width:127px" %)4088H|(% style="width:954px" %)The same pulse output axis (d1) is used and has been started.
828 828  
829 -= {{id name="_Toc3904"/}}**{{id name="_Toc11943"/}}{{id name="_Toc18707"/}}PLSV/DPLSV/Variable speed operation** =
831 +== {{id name="_Toc3904"/}}**{{id name="_Toc11943"/}}{{id name="_Toc18707"/}}PLSV/DPLSV/Variable speed operation** ==
830 830  
831 831  **PLSV/DPLSV**
832 832  
... ... @@ -868,7 +868,7 @@
868 868  • The pulse frequency could be modified while the instruction is running.
869 869  
870 870  (% style="text-align:center" %)
871 -[[image:08_html_2521cc1e50e799ab.gif||height="394" width="700" class="img-thumbnail"]]
873 +[[image:08_html_2521cc1e50e799ab.gif||class="img-thumbnail" height="394" width="700"]]
872 872  
873 873  **✎Note:**
874 874  
... ... @@ -896,9 +896,9 @@
896 896  The sending pulse is as follows:
897 897  
898 898  (% style="text-align:center" %)
899 -[[image:08_html_ac71a602fee1445e.gif||height="387" width="700" class="img-thumbnail"]]
901 +[[image:08_html_ac71a602fee1445e.gif||class="img-thumbnail" height="387" width="700"]]
900 900  
901 -= {{id name="_Toc8609"/}}**{{id name="_Toc662"/}}{{id name="_Toc30652"/}}PLSY/DPLSY/Pulse output** =
903 +== {{id name="_Toc8609"/}}**{{id name="_Toc662"/}}{{id name="_Toc30652"/}}PLSY/DPLSY/Pulse output** ==
902 902  
903 903  **PLSY/DPLSY**
904 904  
... ... @@ -940,7 +940,7 @@
940 940  • The instruction pulse output has no acceleration/deceleration process.
941 941  
942 942  (% style="text-align:center" %)
943 -[[image:08_html_2c248b954bdddae3.gif||height="356" width="700" class="img-thumbnail"]]
945 +[[image:08_html_2c248b954bdddae3.gif||class="img-thumbnail" height="356" width="700"]]
944 944  
945 945  **✎Note:**
946 946  
... ... @@ -964,7 +964,7 @@
964 964  [[image:08_html_ba12be0aaf3caf40.png||class="img-thumbnail"]]
965 965  
966 966  (% style="text-align:center" %)
967 -[[image:08_html_97583e8621e6ae69.png||height="143" width="600" class="img-thumbnail"]]
969 +[[image:08_html_97583e8621e6ae69.png||class="img-thumbnail" height="143" width="600"]]
968 968  
969 969  **(2) Pulse output: positioning address (operand (n))> 0**
970 970  
... ... @@ -973,9 +973,9 @@
973 973  [[image:08_html_87bd5854f06006b0.png]]
974 974  
975 975  (% style="text-align:center" %)
976 -[[image:08_html_97583e8621e6ae69.png||height="143" width="600" class="img-thumbnail"]]
978 +[[image:08_html_97583e8621e6ae69.png||class="img-thumbnail" height="143" width="600"]]
977 977  
978 -= {{id name="_Toc10375"/}}**{{id name="_Toc17757"/}}PWM/BIN 16-bit pulse output** =
980 +== {{id name="_Toc10375"/}}**{{id name="_Toc17757"/}}PWM/BIN 16-bit pulse output** ==
979 979  
980 980  **PWM**
981 981  
... ... @@ -1020,7 +1020,7 @@
1020 1020  • The pulse width and pulse period can be modified during pulse sending.
1021 1021  
1022 1022  (% style="text-align:center" %)
1023 -[[image:08_html_b54cf8e0b0b86ddb.png||height="195" width="600" class="img-thumbnail"]]
1025 +[[image:08_html_b54cf8e0b0b86ddb.png||class="img-thumbnail" height="195" width="600"]]
1024 1024  )))
1025 1025  
1026 1026  **✎Note:**
... ... @@ -1051,9 +1051,9 @@
1051 1051  The waveform diagram is shown as right.
1052 1052  
1053 1053  (% style="text-align:center" %)
1054 -[[image:08_html_f38f59f98fdc96c0.png||height="213" width="600" class="img-thumbnail"]]
1056 +[[image:08_html_f38f59f98fdc96c0.png||class="img-thumbnail" height="213" width="600"]]
1055 1055  
1056 -= **PWM/PWM perimeter mode** =
1058 +== **PWM/PWM perimeter mode** ==
1057 1057  
1058 1058  **PWM**
1059 1059  
... ... @@ -1143,7 +1143,7 @@
1143 1143  (% style="text-align:center" %)
1144 1144  [[image:08_html_13acf8747e8703ff.png||class="img-thumbnail"]]
1145 1145  
1146 -= **G90G01 Absolute position line interpolation instruction** =
1148 +== {{id name="_Toc26527"/}}**{{id name="_Toc9670"/}}{{id name="_Toc32423"/}}{{id name="_Toc27238"/}}G90G01 Absolute position line interpolation instruction** ==
1147 1147  
1148 1148  **G90G01**
1149 1149  
... ... @@ -1183,7 +1183,7 @@
1183 1183  This instruction outputs pulses according to the specified port, frequency and running direction, and performs 2-axis/3-axis line interpolation, and servo actuator runs to the target position according to the line interpolation.
1184 1184  
1185 1185  (% style="text-align:center" %)
1186 -[[image:08_html_af156a7b9cc09d34.jpg||height="324" width="700" class="img-thumbnail"]]
1188 +[[image:08_html_af156a7b9cc09d34.jpg||class="img-thumbnail" height="324" width="700"]]
1187 1187  
1188 1188  * (s1) is the starting address, and occupies 6 consecutive addresses. s1 is the target position (absolute positioning) of X axis , s1+2 is the target position (absolute positioning) of Y axis, and s1+4 is the target position (absolute positioning) of Z axis. The range is -2147483648 to +2147483647.
1189 1189  
... ... @@ -1221,16 +1221,16 @@
1221 1221  |4085H|The result output in the read application instruction (s1), (s2), (d1) and (d2) exceed the device range
1222 1222  |4088H|The same pulse output axis (d1) is used and has been started.
1223 1223  
1224 -**Example**
1226 +**{{id name="_Toc29603"/}}Example**
1225 1225  
1226 1226  (% style="text-align:center" %)
1227 -[[image:image-20220921163523-1.jpeg||class="img-thumbnail"]]
1229 +[[image:08_html_c30d92ae8a2303e1.png||class="img-thumbnail"]]
1228 1228  
1229 1229  Set Y0 as the interpolation starting axis, Y5 as the direction starting axis, and the maximum speed is 2000, the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a absolute position line interpolation output based on the original position which is with acceleration and deceleration, and the end position is X (Y0) axis 100, Y (Y1) axis 100, and the pulse synthesis frequency is 1000.
1230 1230  
1231 -= **G91G01 Relative position line interpolation instruction** =
1233 +== {{id name="_Ref31771"/}}**{{id name="_Toc17391"/}}{{id name="_Toc10640"/}}{{id name="_Toc32642"/}}G91G01 Relative position line interpolation instruction** ==
1232 1232  
1233 -**G91G01**
1235 +{{id name="OLE_LINK10"/}}{{id name="_Toc20742"/}}**G91G01**
1234 1234  
1235 1235  Execute 2 axis/3 axis line interpolation instruction in relative drive mode. The method of specifying the movement distance from the current position is also called incremental(relative) drive mode.
1236 1236  
... ... @@ -1268,7 +1268,7 @@
1268 1268  This instruction outputs pulses according to the specified port, frequency and running direction, and performs 2-axis line interpolation, and servo actuator performs 2-axis line interpolation with a given offset based on the current position.
1269 1269  
1270 1270  (% style="text-align:center" %)
1271 -[[image:08_html_b587806f5f71987d.jpg||height="371" width="800" class="img-thumbnail"]]
1273 +[[image:08_html_b587806f5f71987d.jpg||class="img-thumbnail" height="371" width="800"]]
1272 1272  
1273 1273  * (s1) is the starting address, and occupies 6 consecutive addresses. s1 is the target position (relative positioning) of X axis , s1+2 is the target position (relative positioning) of Y axis, and s1+4 is the target position (relative positioning) of Z axis. The range is -2147483648 to +2147483647.
1274 1274  
... ... @@ -1306,11 +1306,12 @@
1306 1306  
1307 1307  **{{id name="_Toc16441"/}}Example**
1308 1308  
1309 -[[image:image-20220921163600-2.png]]
1311 +(% style="text-align:center" %)
1312 +[[image:08_html_c30d92ae8a2303e1.png||class="img-thumbnail"]]
1310 1310  
1311 1311  {{id name="_Toc26903"/}}Set Y0 as the interpolation starting axis, Y5 as the direction starting axis, and the maximum speed is 2000, and the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a relative position line interpolation output based on the relative position which is with acceleration and deceleration , and the incremental position is X (Y0) axis 100, Y (Y1) axis 100, and the pulse synthesis frequency is 1000.
1312 1312  
1313 -= {{id name="_Ref31781"/}}**{{id name="_Toc27199"/}}{{id name="_Toc11517"/}}{{id name="_Toc20314"/}}{{id name="OLE_LINK11"/}}G90G02 Absolute position clockwise circular interpolation instruction** =
1316 +== {{id name="_Ref31781"/}}**{{id name="_Toc27199"/}}{{id name="_Toc11517"/}}{{id name="_Toc20314"/}}{{id name="OLE_LINK11"/}}G90G02 Absolute position clockwise circular interpolation instruction** ==
1314 1314  
1315 1315  **G90G02**
1316 1316  
... ... @@ -1348,7 +1348,7 @@
1348 1348  {{id name="OLE_LINK12"/}}This instruction outputs pulses according to the specified port, frequency and running direction, and performs 2-axis clockwise circular interpolation, and servo actuator performs clockwise circular interpolation to run to the target position point.
1349 1349  
1350 1350  (% style="text-align:center" %)
1351 -[[image:08_html_ca40f9fe262dab7.jpg||height="482" width="800" class="img-thumbnail"]]
1354 +[[image:08_html_ca40f9fe262dab7.jpg||class="img-thumbnail" height="482" width="800"]]
1352 1352  
1353 1353  * (s1) is the starting address, and occupies 6 consecutive addresses. s1 is the target position (absolute positioning) of X axis , s1+2 is the target position (absolute positioning) of Y axis, and s1+4 is the target position (absolute positioning) of Z axis. The range is -2147483648 to +2147483647.
1354 1354  * Specify radius or center mode in (s2), and occupy 4 consecutive addresses. The center coordinate of s2+0 is in the difference value of the number of pulse output of X axis relative to the current position, or the number of the pulse of radius R. The center coordinate of s2+2 is in the difference value of the number of pulse output of Y axis relative to the current position. When using radius, the value must be 0X7FFF FFFF. The range is 1 to 141421.
... ... @@ -1393,11 +1393,11 @@
1393 1393  **{{id name="OLE_LINK268"/}}Example**
1394 1394  
1395 1395  (% style="text-align:center" %)
1396 -[[image:image-20220921163619-3.png||class="img-thumbnail"]]
1399 +[[image:08_html_c30d92ae8a2303e1.png||class="img-thumbnail"]]
1397 1397  
1398 1398  Set Y0 as the interpolation starting axis, Y5 as the direction starting axis, and the maximum speed is 2000, and the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a absolute position clockwise circular interpolation output based on the absolute position with acceleration and deceleration, and the target position is X (Y0) axis 100, Y (Y1) axis 100, and the the radius is 1000 pulse in radius mode, and the pulse synthesis frequency is 1000.
1399 1399  
1400 -= **G91G02 Relative position clockwise circular interpolation instruction** =
1403 +== **G91G02 Relative position clockwise circular interpolation instruction** ==
1401 1401  
1402 1402  **G91G02**
1403 1403  
... ... @@ -1439,7 +1439,7 @@
1439 1439  This instruction outputs pulses according to the specified port, frequency and running direction, performs 2-axis clockwise circular interpolation, and servo actuator performs 2-axis clockwise circular interpolation with a given offset based in current position.
1440 1440  
1441 1441  (% style="text-align:center" %)
1442 -[[image:08_html_af9751b2294f613b.jpg||height="482" width="800" class="img-thumbnail"]]
1445 +[[image:08_html_af9751b2294f613b.jpg||class="img-thumbnail" height="482" width="800"]]
1443 1443  
1444 1444  * {{id name="OLE_LINK18"/}}s1 is the starting address, and occupies 4 consecutive addresses. s1 is the target position of X axis (relative positioning), s1+2 is the target position of Y axis (relative positioning). The range is -2147483648 to +2147483647.
1445 1445  * {{id name="OLE_LINK20"/}}Specify radius or center mode in (s2), and occupy 4 consecutive addresses. The center coordinate of s2+0 is in the difference value of the number of pulse output of X axis relative to the current position, or the number of the pulse of radius R. The center coordinate of s2+2 is in the difference value of the number of pulse output of Y axis relative to the current position. When using radius, the value must be 0X7FFF FFFF. The range is 1 to 141421.
... ... @@ -1484,11 +1484,11 @@
1484 1484  **Example**{{id name="OLE_LINK22"/}}
1485 1485  
1486 1486  (% style="text-align:center" %)
1487 -[[image:image-20220921163641-4.png||class="img-thumbnail"]]
1490 +[[image:08_html_c30d92ae8a2303e1.png||class="img-thumbnail"]]
1488 1488  
1489 1489  {{id name="OLE_LINK21"/}}Set Y0 as the interpolation starting axis, Y5 as the direction starting axis, and the maximum speed is 2000, and the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a relative position clockwise circular interpolation output based on relative position with acceleration and deceleration, and the incremental position is X (Y0) axis 100, Y (Y1) axis 100, and the the radius is 1000 pulse in radius mode, and the pulse synthesis frequency is 1000.
1490 1490  
1491 -= **G90G03 Absolute position counterclockwise circular interpolation instruction** =
1494 +== **G90G03 Absolute position counterclockwise circular interpolation instruction** ==
1492 1492  
1493 1493  G90G03
1494 1494  
... ... @@ -1530,7 +1530,7 @@
1530 1530  This instruction outputs pulses according to the specified port, frequency and running direction, performs 2-axis counterclockwise circular interpolation, and the servo actuator performs counterclockwise circular interpolation to run to the target position point.
1531 1531  
1532 1532  (% style="text-align:center" %)
1533 -[[image:08_html_7ad9ac91f5066720.jpg||height="491" width="800" class="img-thumbnail"]]
1536 +[[image:08_html_7ad9ac91f5066720.jpg||class="img-thumbnail" height="491" width="800"]]
1534 1534  
1535 1535  * s1 is the starting address, and occupies 4 consecutive addresses. s1 is the target position of X axis (absolute positioning), s1+2 is the target position of Y axis (absolute positioning). The range is -2147483648 to +2147483647.
1536 1536  * Specify radius or center mode in (s2), and occupy 4 consecutive addresses. The center coordinate of s2+0 is in the difference value of the number of pulse output of X axis relative to the current position, or the number of the pulse of radius R. The center coordinate of s2+2 is in the difference value of the number of pulse output of Y axis relative to the current position. When using radius, the value must be 0X7FFF FFFF. The range is 1 to 141421.
... ... @@ -1575,11 +1575,11 @@
1575 1575  **Example**
1576 1576  
1577 1577  (% style="text-align:center" %)
1578 -[[image:image-20220921163737-5.png||class="img-thumbnail"]]
1581 +[[image:08_html_c30d92ae8a2303e1.png||class="img-thumbnail"]]
1579 1579  
1580 1580  Set Y0 as the interpolation starting axis, Y5 as the direction starting axis, the maximum speed is 2000, the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a absolute position counterclockwise circular interpolation output based on relative position with acceleration and deceleration, and the target position is X (Y0) axis 100, Y (Y1) axis 100, and the the radius is 1000 pulse in radius mode, and the pulse synthesis frequency is 1000.
1581 1581  
1582 -= {{id name="_Ref31892"/}}**{{id name="_Toc1720"/}}{{id name="_Toc12908"/}}{{id name="_Toc10325"/}}G91G03 Relative position counterclockwise circular interpolation instruction** =
1585 +== {{id name="_Ref31892"/}}**{{id name="_Toc1720"/}}{{id name="_Toc12908"/}}{{id name="_Toc10325"/}}G91G03 Relative position counterclockwise circular interpolation instruction** ==
1583 1583  
1584 1584  **G91G03**
1585 1585  
... ... @@ -1621,7 +1621,7 @@
1621 1621  This instruction outputs pulses according to the specified port, frequency and running direction, performs 2-axis counterclockwise circular interpolation, and servo actuator performs a 2-axis counterclockwise circular interpolation with a given offset based in current position.
1622 1622  
1623 1623  (% style="text-align:center" %)
1624 -[[image:08_html_445649f805e910a5.jpg||height="491" width="800" class="img-thumbnail"]]
1627 +[[image:08_html_445649f805e910a5.jpg||class="img-thumbnail" height="491" width="800"]]
1625 1625  
1626 1626  * s1 is the starting address, and occupies 4 consecutive addresses. s1 is the target position of X axis (absolute positioning), s1+2 is the target position of Y axis (absolute positioning). The range is -2147483648 to +2147483647.
1627 1627  * Specify radius or center mode in (s2), and occupy 4 consecutive addresses. The center coordinate of s2+0 is in the difference value of the number of pulse output of X axis relative to the current position, or the number of the pulse of radius R. The center coordinate of s2+2 is in the difference value of the number of pulse output of Y axis relative to the current position. When using radius, the value must be 0X7FFF FFFF. The range is 1 to 141421.
... ... @@ -1666,11 +1666,11 @@
1666 1666  **Example**
1667 1667  
1668 1668  (% style="text-align:center" %)
1669 -[[image:image-20220921163754-6.png]]
1672 +[[image:08_html_c30d92ae8a2303e1.png||class="img-thumbnail"]]
1670 1670  
1671 1671  Set Y0 as the interpolation starting axis, Y5 as the direction starting axis, the maximum speed is 2000, the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a relative position reverse circular interpolation output based on relative position with acceleration and deceleration, and the incremental position is X (Y0) axis 100, Y (Y1) axis 100, and the the radius is 1000 pulse in radius mode, and the pulse synthesis frequency is 1000.
1672 1672  
1673 -= {{id name="_Ref31901"/}}**{{id name="_Toc7584"/}}{{id name="_Toc8429"/}}{{id name="_Toc13595"/}}{{id name="_Toc10219"/}}G90G02H Absolute position clockwise circular helical interpolation instruction** =
1676 +== {{id name="_Ref31901"/}}**{{id name="_Toc7584"/}}{{id name="_Toc8429"/}}{{id name="_Toc13595"/}}{{id name="_Toc10219"/}}G90G02H Absolute position clockwise circular helical interpolation instruction** ==
1674 1674  
1675 1675  **G90G02H**
1676 1676  
... ... @@ -1714,7 +1714,7 @@
1714 1714  (% style="text-align:center" %)
1715 1715  [[image:08_html_769e3269fb4c782e.png||class="img-thumbnail"]]
1716 1716  
1717 -* (s1) is the starting address, and occupies 8 consecutive addresses. s1 is the target position (absolute positioning) of X axis , s1+2 is the target position (absolute positioning) of Y axis, and s1+4 is the target position (absolute positioning) of Z axis, and s1+6 is the lead range of Z axis. The lead range is [[image:image-20220921171331-1.png||height="31" width="113"]],, ,,.(The range is -2147483648 to +2147483647.)
1720 +* (s1) is the starting address, and occupies 8 consecutive addresses. s1 is the target position (absolute positioning) of X axis , s1+2 is the target position (absolute positioning) of Y axis, and s1+4 is the target position (absolute positioning) of Z axis, and s1+6 is the lead range of Z axis. The lead range is,,[[image:08_html_8d829d6ac7cb190d.gif]] ,,.(The range is -2147483648 to +2147483647.)
1718 1718  * Specify radius or center mode in (s2), and occupy 4 consecutive addresses. The coordinate of circle center of s2+0 is in the difference value of the number of pulse output of X axis relative to the current position, or the number of the pulse of radius R. The coordinate of circle center of s2+2 is in the difference value of the number of pulse output of Y axis relative to the current position. When using radius, the value must be 0X7FFF FFFF. The range is 1 to 141421.
1719 1719  
1720 1720  * Specify the synthetic output frequency in (s3) . The range is 1 to 100000. Helical interpolation can switch the synthetic frequency by setting SM901. 0 means default, and the synthetic frequency is the frequency of the linear velocity of helix. 1 means that the synthetic frequency is the frequency of the linear velocity of the arc of arc plane, that is, the actual synthetic frequency is greater than the setting synthetic frequency.
... ... @@ -1734,7 +1734,7 @@
1734 1734  
1735 1735  (5) IJ mode: Regardless of absolute position interpolation or relative position interpolation, s2 is only expressed as the difference of the pulse output number between the coordinates of circle center on the XY axis (Y0/Y1) relative to the current position, and both are in the offset value.
1736 1736  
1737 -(6) In helical interpolation R mode (radius mode): When the value of R is greater than 0, it indicates that from the starting point coordinate to the set end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from the starting point coordinate to the set end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K. (If Ze=75, lead K=50, and the actual radian [[image:image-20220921171348-2.png||height="47" width="90"]],,),,
1740 +(6) In helical interpolation R mode (radius mode): When the value of R is greater than 0, it indicates that from the starting point coordinate to the set end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from the starting point coordinate to the set end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K. ( If Ze=75, lead K=50, and the actual radian ,,[[image:08_html_16dfa306a6cd6123.gif||class="img-thumbnail"]] ,,)
1738 1738  
1739 1739  (7) When using the interpolation instruction, parameter settings (such as acceleration/deceleration time and so on) are subject to the X axis (Y0);
1740 1740  
... ... @@ -1746,16 +1746,15 @@
1746 1746  (% style="text-align:center" %)
1747 1747  [[image:08_html_6854958a7732277a.gif||class="img-thumbnail"]]
1748 1748  
1749 -(9) Exact match pitch of screws (lead) K and Ze,,.,,
1752 +(9) Exact match pitch of screws (lead) K and ,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] .,,
1750 1750  
1751 -The starting point coordinate of helical interpolation is (0,0,0),, ,,, set the end point coordinate to (Xe,Ye,Ze), the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif||class="img-thumbnail"]] is determined by formula (1), and recalculate the end point coordinates (Xe',Ye') of X axis and Y axis according to the number of turns of interpolation.
1754 +The starting point coordinate of helical interpolation is ,,[[image:08_html_5aecdb267e93e1ef.gif||class="img-thumbnail"]] ,,, set the end point coordinate to ,,[[image:08_html_62eafa46570f5bd9.gif||class="img-thumbnail"]] ,,,the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif||class="img-thumbnail"]] is determined by formula (1), and recalculate the end point coordinates of X axis and Y axis according to the number of turns of interpolation.
1752 1752  
1753 -The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to Ze,, ,,.The actual end point position of X and Y axes  (Xe',Ye') ,, ,,may not be equal to the set  (Xe,Ye), but it must pass through the set point (Xe,Ye), in the whole circle.
1756 +The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] ,,.The actual end point position of X and Y axes ,,[[image:08_html_812f611042b80df0.gif||class="img-thumbnail"]] ,,may not be equal to the set ,,[[image:08_html_72a7340925bd2eea.gif||class="img-thumbnail"]] ,,, but it must pass through the set point ,,[[image:08_html_72a7340925bd2eea.gif||class="img-thumbnail"]] ,,in the whole circle.
1754 1754  
1755 -(% style="text-align:center" %)
1756 -[[image:image-20220921171411-3.png||height="62" width="312"]]
1758 +,,[[image:08_html_d3f40984948fb2f1.gif||class="img-thumbnail"]] ,,(1)
1757 1757  
1758 -(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the starting point coordinate (0,0,0), the end point coordinate (0,0,Ze).
1760 +(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the starting point coordinate ,,[[image:08_html_3ed96de3414e2c4d.gif]] ,,,the end point coordinate,,[[image:08_html_a9e3b53d7dfa134a.gif||class="img-thumbnail"]] ,,).
1759 1759  
1760 1760  (% class="table-bordered" %)
1761 1761  |**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**|**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**
... ... @@ -1776,16 +1776,16 @@
1776 1776  |(% style="width:139px" %)4F97H|(% style="width:942px" %)In center mode, the calculated radius distance is greater than the maximum radius range, which is positive or negative 800,000 pulse.
1777 1777  |(% style="width:139px" %)4F98H|(% style="width:942px" %)Helical interpolation error, Z axis is the main axis.(The coordinate of Z axis is greater than the number of of virtual main axis of circular plane)
1778 1778  |(% style="width:139px" %)4F99H|(% style="width:942px" %)Helical interpolation error, Z axis is 0.
1779 -|(% style="width:139px" %)4F9BH|(% style="width:942px" %)Lead setting exceeds the range.(Lead,, ,,[[image:image-20220921171529-5.png||height="32" width="69"]],, ,,)
1781 +|(% style="width:139px" %)4F9BH|(% style="width:942px" %)Lead setting exceeds the range.(Lead ,,[[image:08_html_63ad102f937fdad0.gif]] ,,)
1780 1780  
1781 1781  **{{id name="_Toc12418"/}}Example**
1782 1782  
1783 1783  (% style="text-align:center" %)
1784 -[[image:image-20220921163843-7.png||class="img-thumbnail"]]
1786 +[[image:08_html_61693f5f524ad69e.png||class="img-thumbnail"]]
1785 1785  
1786 1786  Set Y0 as the interpolation starting axis, Y4 as the direction starting axis, and the maximum speed is 2000, and the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a absolute position clockwise circular helical interpolation output based on the absolute position with acceleration and deceleration, and the target position is X (Y0) axis 0, Y (Y1) axis 0 and Z (Y2) axis 5000, and the lead is 5000, and the radius is 5000 pulse in radius mode, and the synthesis frequency is 1000.
1787 1787  
1788 -= {{id name="_Ref31918"/}}**{{id name="_Toc12793"/}}{{id name="_Toc9051"/}}{{id name="_Toc18572"/}}G91G02H Relative position clockwise circular helical interpolation instruction** =
1790 +== {{id name="_Ref31918"/}}**{{id name="_Toc12793"/}}{{id name="_Toc9051"/}}{{id name="_Toc18572"/}}G91G02H Relative position clockwise circular helical interpolation instruction** ==
1789 1789  
1790 1790  **G91G02H**
1791 1791  
... ... @@ -1829,7 +1829,7 @@
1829 1829  (% style="text-align:center" %)
1830 1830  [[image:08_html_769e3269fb4c782e.png||class="img-thumbnail"]]
1831 1831  
1832 -* (s1) is the starting address, and occupies 8 consecutive addresses. s1 is the target position (relative positioning) of X axis , s1+2 is the target position (relative positioning) of Y axis, and s1+4 is the target position (relative positioning) of Z axis, and s1+6 is the lead range of Z axis. The lead range is,, ,,[[image:image-20220921171628-6.png||height="29" width="106"]]. (The range is -2147483648 to +2147483647.)
1834 +* (s1) is the starting address, and occupies 8 consecutive addresses. s1 is the target position (relative positioning) of X axis , s1+2 is the target position (relative positioning) of Y axis, and s1+4 is the target position (relative positioning) of Z axis, and s1+6 is the lead range of Z axis. The lead range is,,[[image:08_html_8d829d6ac7cb190d.gif]] ,,.(The range is -2147483648 to +2147483647.)
1833 1833  * Specify radius or center mode in (s2), and occupy 4 consecutive addresses. The coordinate of circle center of s2+0 is in the difference value of the number of pulse output of X axis relative to the current position, or the number of the pulse of radius R. The coordinate of circle center of s2+2 is in the difference value of the number of pulse output of Y axis relative to the current position. When using radius, the value must be 0X7FFF FFFF. The range is 1 to 141421.
1834 1834  
1835 1835  * Specify the synthetic output frequency in (s3). The range is 1 to 100000. Helical interpolation can switch the synthetic frequency by setting SM901. 0 means default, and the synthetic frequency is the frequency of the linear velocity of helix. 1 means that the synthetic frequency is the frequency of the linear velocity of the arc of arc plane, that is, the actual synthetic frequency is greater than the setting synthetic frequency.
... ... @@ -1849,10 +1849,8 @@
1849 1849  
1850 1850  (5) IJ mode: Regardless of absolute position interpolation or relative position interpolation, s2 is only expressed as the difference of the pulse output number between the coordinates of the circle center on the XY axis (Y0/Y1) relative to the current position, and both are in the offset value.
1851 1851  
1852 -(6) In helical interpolation R mode (radius mode) : When the value of R is greater than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K.
1854 +(6) In helical interpolation R mode (radius mode) : When the value of R is greater than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K. ( If Ze=75, lead K=50, and the actual radian ,,[[image:08_html_16dfa306a6cd6123.gif||class="img-thumbnail"]] ,,)
1853 1853  
1854 -(If Ze=75, lead K=50, and the actual radian [[image:image-20220921171639-7.png||height="56" width="107"]],,),,
1855 -
1856 1856  (7) When using interpolation instruction, parameter settings (such as acceleration/deceleration time and so on) are subject to the X axis (Y0);
1857 1857  
1858 1858  (8) The actual synthetic frequency S (the lowest frequency value) is the lowest base frequency of the output synthetic frequency. The calculation modes are as follows:
... ... @@ -1863,16 +1863,15 @@
1863 1863  (% style="text-align:center" %)
1864 1864  [[image:08_html_6854958a7732277a.gif||class="img-thumbnail"]]
1865 1865  
1866 -(9) Exact match pitch of screws (lead) K and Ze,,.,,
1866 +(9) Exact match pitch of screws (lead) K and ,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] .,,
1867 1867  
1868 -The starting point coordinate of helical interpolation is (0,0,0), set the end point coordinate to (Xe,Ye,Ze), the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif]] is determined by formula (1), and recalculate the end point coordinates (Xe‘,Ye’) of X axis and Y axis according to the number of turns of interpolation.
1868 +The starting point coordinate of helical interpolation is ,,[[image:08_html_5aecdb267e93e1ef.gif||class="img-thumbnail"]] ,,, set the end point coordinate to ,,[[image:08_html_62eafa46570f5bd9.gif||class="img-thumbnail"]] ,,,the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif]] is determined by formula (1), and recalculate the end point coordinates of X axis and Y axis according to the number of turns of interpolation.
1869 1869  
1870 -The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to Ze,, ,,.The actual end point position of X and Y axes (Xe‘,Ye’) ,, ,,may not be equal to the set (Xe,Ye) ,, ,,, but it must pass through the set poin (Xe,Ye) ,, ,,in the whole circle.
1870 +The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] ,,.The actual end point position of X and Y axes ,,[[image:08_html_812f611042b80df0.gif||class="img-thumbnail"]] ,,may not be equal to the set ,,[[image:08_html_72a7340925bd2eea.gif||class="img-thumbnail"]] ,,, but it must pass through the set point ,,[[image:08_html_72a7340925bd2eea.gif||class="img-thumbnail"]] ,,in the whole circle.
1871 1871  
1872 -(% style="text-align:center" %)
1873 -[[image:image-20220921171703-8.png||height="58" width="291"]]
1872 +,,[[image:08_html_d3f40984948fb2f1.gif||class="img-thumbnail"]] ,,(1)
1874 1874  
1875 -(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the starting point coordinate (0,0,0),, ,,,the end point coordinate (0,0,Ze),, ,,.
1874 +(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the starting point coordinate ,,[[image:08_html_3ed96de3414e2c4d.gif]] ,,,the end point coordinate,,[[image:08_html_a9e3b53d7dfa134a.gif]] ,,).
1876 1876  
1877 1877  (% class="table-bordered" %)
1878 1878  |**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**|**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**
... ... @@ -1893,16 +1893,16 @@
1893 1893  |(% style="width:129px" %)4F97H|(% style="width:952px" %)In center mode, the calculated radius distance is greater than the maximum radius range, which is positive or negative 800,000 pulse.
1894 1894  |(% style="width:129px" %)4F98H|(% style="width:952px" %)Helical interpolation error, Z axis is the main axis.(The coordinate of Z axis is greater than the number of of virtual main axis of circular plane)
1895 1895  |(% style="width:129px" %)4F99H|(% style="width:952px" %)Helical interpolation error, Z axis is 0.
1896 -|(% style="width:129px" %)4F9BH|(% style="width:952px" %)Lead setting exceeds the range.(Lead[[image:image-20220921171735-9.png||height="28" width="59"]])
1895 +|(% style="width:129px" %)4F9BH|(% style="width:952px" %)Lead setting exceeds the range.(Lead ,,[[image:08_html_63ad102f937fdad0.gif]] ,,)
1897 1897  
1898 1898  **{{id name="_Toc28830"/}}Example**
1899 1899  
1900 1900  (% style="text-align:center" %)
1901 -[[image:image-20220921163904-8.png]]
1900 +[[image:08_html_61693f5f524ad69e.png||class="img-thumbnail"]]
1902 1902  
1903 1903  Set Y0 as the interpolation starting axis, Y4 as the direction start axis, and the maximum speed is 2000, and the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a relative position clockwise circular helical interpolation output based on the relative position with acceleration and deceleration, and the target position is X (Y0) axis 0, Y (Y1) axis 0 and Z (Y2) axis 5000, and the lead is 5000, and the radius is 5000 pulse in radius mode, and the synthesis frequency is 1000.
1904 1904  
1905 -= {{id name="_Ref31924"/}}**{{id name="_Toc4668"/}}{{id name="_Toc28191"/}}{{id name="_Toc24432"/}}G90G03H Absolute position counterclockwise circular helical interpolation instruction** =
1904 +== {{id name="_Ref31924"/}}**{{id name="_Toc4668"/}}{{id name="_Toc28191"/}}{{id name="_Toc24432"/}}G90G03H Absolute position counterclockwise circular helical interpolation instruction** ==
1906 1906  
1907 1907  **G90G03H**
1908 1908  
... ... @@ -1946,8 +1946,7 @@
1946 1946  (% style="text-align:center" %)
1947 1947  [[image:08_html_769e3269fb4c782e.png||class="img-thumbnail"]]
1948 1948  
1949 -* (s1) is the starting address, and occupies 8 consecutive addresses. s1 is the target position (absolute positioning) of X axis , s1+2 is the target position (absolute positioning) of Y axis, and s1+4 is the target position (absolute positioning) of Z axis, and s1+6 is the lead range of Z axis.
1950 -* The lead range is [[image:image-20220921171807-10.png||height="35" width="128"]]. (The range is -2147483648 to +2147483647.)
1948 +* (s1) is the starting address, and occupies 8 consecutive addresses. s1 is the target position (absolute positioning) of X axis , s1+2 is the target position (absolute positioning) of Y axis, and s1+4 is the target position (absolute positioning) of Z axis, and s1+6 is the lead range of Z axis. The lead range is,,[[image:08_html_8d829d6ac7cb190d.gif]] ,,.(The range is -2147483648 to +2147483647.)
1951 1951  * Specify radius or center mode in (s2), and occupy 4 consecutive addresses. The coordinate of circle center of s2+0 is in the difference value of the number of pulse output of X axis relative to the current position, or the number of the pulse of radius R. The coordinate of circle center of s2+2 is in the difference value of the number of pulse output of Y axis relative to the current position. When using radius, the value must be 0X7FFF FFFF. The range is 1 to 141421.
1952 1952  
1953 1953  * Specify the synthetic output frequency in (s3). The range is 1 to 100000. Helical interpolation can switch the synthetic frequency by setting SM901. 0 means default, and the synthetic frequency is the frequency of the linear velocity of helix. 1 means that the synthetic frequency is the frequency of the linear velocity of the arc of arc plane, that is, the actual synthetic frequency is greater than the setting synthetic frequency.
... ... @@ -1967,10 +1967,8 @@
1967 1967  
1968 1968  (5) IJ mode: Regardless of absolute position interpolation or relative position interpolation, s2 is only expressed as the difference of the pulse output number between the coordinates of the center of the circle on the XY axis (Y0/Y1) relative to the current position, and both are in the offset value.
1969 1969  
1970 -(6) In helical interpolation R mode (radius mode): When the value of R is greater than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K.
1968 +(6) In helical interpolation R mode (radius mode): When the value of R is greater than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K. ( If Ze=75, lead K=50, and the actual radian ,,[[image:08_html_16dfa306a6cd6123.gif||class="img-thumbnail"]] ,,)
1971 1971  
1972 -If Ze=75, lead K=50, and the actual radian(% style="font-size:10.5px" %) [[image:image-20220921171852-11.png||height="65" width="124"]]
1973 -
1974 1974  (7) When using the interpolation instruction, parameter settings (such as acceleration/deceleration time and so on) are subject to the X axis (Y0);
1975 1975  
1976 1976  (8) The actual synthetic frequency S (the lowest frequency value) is the lowest base frequency of the output synthetic frequency. The calculation modes are as follows:
... ... @@ -1981,16 +1981,15 @@
1981 1981  (% style="text-align:center" %)
1982 1982  [[image:08_html_6854958a7732277a.gif||class="img-thumbnail"]]
1983 1983  
1984 -(9) Exact match pitch of screws (lead) K and Ze
1980 +(9) Exact match pitch of screws (lead) K and ,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] .,,
1985 1985  
1986 -The starting point coordinate of helical interpolation is (0,0,0),, ,,, set the end point coordinate to (Xe,Ye,Ze), the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif]] is determined by formula (1), and recalculate the end point coordinates of X axis and Y axis according to the number of turns of interpolation.
1982 +The starting point coordinate of helical interpolation is ,,[[image:08_html_5aecdb267e93e1ef.gif||class="img-thumbnail"]] ,,, set the end point coordinate to ,,[[image:08_html_62eafa46570f5bd9.gif||class="img-thumbnail"]] ,,,the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif]] is determined by formula (1), and recalculate the end point coordinates of X axis and Y axis according to the number of turns of interpolation.
1987 1987  
1988 -The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to Ze,, ,,.The actual end point position of X and Y axes (Xe',Ye'),, ,,may not be equal to the set (Xe,Ye),, ,,, but it must pass through the set point (Xe,Ye),, ,,in the whole circle.
1984 +The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] ,,.The actual end point position of X and Y axes ,,[[image:08_html_812f611042b80df0.gif]] ,,may not be equal to the set ,,[[image:08_html_72a7340925bd2eea.gif||class="img-thumbnail"]] ,,, but it must pass through the set point ,,[[image:08_html_72a7340925bd2eea.gif||class="img-thumbnail"]] ,,in the whole circle.
1989 1989  
1990 -(% style="text-align:center" %)
1991 -[[image:image-20220921171930-12.png||height="74" width="370"]]
1986 +,,[[image:08_html_d3f40984948fb2f1.gif||class="img-thumbnail"]] ,,(1)
1992 1992  
1993 -(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the starting point coordinate (0,0,0),, ,,,the end point coordinate (0,0,Ze),, ,,).
1988 +(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the starting point coordinate ,,[[image:08_html_3ed96de3414e2c4d.gif||class="img-thumbnail"]] ,,,the end point coordinate,,[[image:08_html_a9e3b53d7dfa134a.gif||class="img-thumbnail"]] ,,).
1994 1994  
1995 1995  (% class="table-bordered" %)
1996 1996  |**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**|**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**
... ... @@ -2011,16 +2011,16 @@
2011 2011  |(% style="width:132px" %)4F97H|(% style="width:949px" %)In center mode, the calculated radius distance is greater than the maximum radius range, which is positive or negative 800,000 pulse.
2012 2012  |(% style="width:132px" %)4F98H|(% style="width:949px" %)Helical interpolation error, Z axis is the main axis.(The coordinate of Z axis is greater than the number of of virtual main axis of circular plane)
2013 2013  |(% style="width:132px" %)4F99H|(% style="width:949px" %)Helical interpolation error, Z axis is 0.
2014 -|(% style="width:132px" %)4F9BH|(% style="width:949px" %)Lead setting exceeds the range. (Lead [[image:image-20220921171956-13.png||height="29" width="61"]])
2009 +|(% style="width:132px" %)4F9BH|(% style="width:949px" %)Lead setting exceeds the range. (Lead ,,[[image:08_html_63ad102f937fdad0.gif]] ,,)
2015 2015  
2016 2016  **{{id name="_Toc18584"/}}Example**
2017 2017  
2018 2018  (% style="text-align:center" %)
2019 -[[image:image-20220921163935-9.png||class="img-thumbnail"]]
2014 +[[image:08_html_61693f5f524ad69e.png||class="img-thumbnail"]]
2020 2020  
2021 2021  Set Y0 as the interpolation starting axis, Y4 as the direction starting axis, and the maximum speed is 2000, and the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a absolute position counterclockwise circular helical interpolation output based on the absolute position with acceleration and deceleration, and the target position is X (Y0) axis 0, Y (Y1) axis 0 and Z (Y2) axis 5000, and the lead is 5000, and the radius is 5000 pulse in radius mode, and the synthesis frequency is 1000.
2022 2022  
2023 -= **G91G03H Relative position counterclockwise circular helical interpolation instruction** =
2018 +== {{id name="_Ref31947"/}}**{{id name="_Toc5018"/}}{{id name="_Toc1347"/}}{{id name="_Toc26018"/}}G91G03H Relative position counterclockwise circular helical interpolation instruction** ==
2024 2024  
2025 2025  **G91G03H**
2026 2026  
... ... @@ -2084,10 +2084,8 @@
2084 2084  
2085 2085  (5) IJ mode: Regardless of absolute position interpolation or relative position interpolation, s2 is only expressed as the difference of the pulse output number between the coordinates of the circle center on the XY axis (Y0/Y1) relative to the current position, and both are in the offset value.
2086 2086  
2087 -(6) In helical interpolation R mode (radius mode) : When the value of R is greater than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K.
2082 +(6) In helical interpolation R mode (radius mode) : When the value of R is greater than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc less than or equal to 180 degrees. When the value of R is less than 0, it indicates that from starting point coordinate to the setting end point coordinate in the circular plane of XY is an arc greater than or equal to 180 degrees, and the actual passing angle is determined by the endpoint of Z axis and the lead K. ( If Ze=75, lead K=50, and the actual radian ,,[[image:08_html_16dfa306a6cd6123.gif||class="img-thumbnail"]] ,,)
2088 2088  
2089 -If Ze=75, lead K=50, and the actual radian [[image:image-20220921172134-15.png||height="68" width="130"]]
2090 -
2091 2091  (7) When using interpolation instruction, parameter settings (such as acceleration/deceleration time and so on) are subject to the X axis (Y0);
2092 2092  
2093 2093  (8) The actual synthetic frequency S (the lowest frequency value) is the lowest base frequency of the output synthetic frequency. The calculation modes are as follows:
... ... @@ -2098,16 +2098,15 @@
2098 2098  (% style="text-align:center" %)
2099 2099  [[image:08_html_6854958a7732277a.gif||class="img-thumbnail"]]
2100 2100  
2101 -(9) Exact match pitch of screws (lead) K and Ze
2094 +(9) Exact match pitch of screws (lead) K and ,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] .,,
2102 2102  
2103 -The start point coordinate of helical interpolation is(0,0,0), set the end point coordinate to (Xe,Ye,Ze),the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif]] is determined by formula (1), and recalculate the end point coordinates of X axis and Y axis according to the number of turns of interpolation.
2096 +The start point coordinate of helical interpolation is ,,[[image:08_html_5aecdb267e93e1ef.gif||class="img-thumbnail"]] ,,, set the end point coordinate to ,,[[image:08_html_62eafa46570f5bd9.gif||class="img-thumbnail"]] ,,,the number of turns of helical interpolation [[image:08_html_f1878c8190771c9b.gif]] is determined by formula (1), and recalculate the end point coordinates of X axis and Y axis according to the number of turns of interpolation.
2104 2104  
2105 -The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to Ze,, ,,.The actual end point position of X and Y axes (Xe',Ye'),, ,,may not be equal to the set (Xe,Ye), but it must pass through the set point (Xe,Ye),, ,,in the whole circle.
2098 +The final interpolation result is: make sure that lead is equal to K, and the end point of Z axis is equal to,,[[image:08_html_26235c6907b42965.gif||class="img-thumbnail"]] ,,.The actual end point position of X and Y axes ,,[[image:08_html_812f611042b80df0.gif||class="img-thumbnail"]] ,,may not be equal to the set ,,[[image:08_html_72a7340925bd2eea.gif]] ,,, but it must pass through the set point ,,[[image:08_html_72a7340925bd2eea.gif||class="img-thumbnail"]] ,,in the whole circle.
2106 2106  
2107 -(% style="text-align:center" %)
2108 -[[image:image-20220921172159-16.png||height="72" width="362"]]
2100 +,,[[image:08_html_d3f40984948fb2f1.gif||class="img-thumbnail"]] ,,(1)
2109 2109  
2110 -(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the start point coordinate (0,0,0), the end point coordinate (0,0,Ze).
2102 +(10) In helical interpolation radius mode, the center distribution table of whole circle is as below. (For example: the start point coordinate ,,[[image:08_html_3ed96de3414e2c4d.gif]] ,,,the end point coordinate,,[[image:08_html_a9e3b53d7dfa134a.gif]] ,,).
2111 2111  
2112 2112  (% class="table-bordered" %)
2113 2113  |**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**|**Helical interpolation direction**|**Radius value R**|**Coordinate of circle center**
... ... @@ -2128,12 +2128,12 @@
2128 2128  |(% style="width:108px" %)4F97H|(% style="width:973px" %)In center mode, the calculated radius distance is greater than the maximum radius range, which is positive or negative 800,000 pulse.
2129 2129  |(% style="width:108px" %)4F98H|(% style="width:973px" %)Helical interpolation error, Z axis is the main axis.(The coordinate of Z axis is greater than the number of of virtual main axis of circular plane)
2130 2130  |(% style="width:108px" %)4F99H|(% style="width:973px" %)Helical interpolation error, Z axis is 0.
2131 -|(% style="width:108px" %)4F9BH|(% style="width:973px" %)Lead setting exceeds the range.(Lead [[image:image-20220921172255-17.png||height="29" width="62"]],, ,,)
2123 +|(% style="width:108px" %)4F9BH|(% style="width:973px" %)Lead setting exceeds the range.(Lead ,,[[image:08_html_63ad102f937fdad0.gif]] ,,)
2132 2132  
2133 2133  **{{id name="_Toc11997"/}}Example**
2134 2134  
2135 2135  (% style="text-align:center" %)
2136 -[[image:image-20220921163953-10.png||class="img-thumbnail"]]
2128 +[[image:08_html_61693f5f524ad69e.png||class="img-thumbnail"]]
2137 2137  
2138 2138  Set Y0 as the interpolation starting axis, Y4 as the direction starting axis, and the maximum speed is 2000, and the offset speed is 500, and the acceleration/deceleration time is 500ms. Send a relative position counterclockwise circular helical interpolation output based on the relative position with acceleration and deceleration, and the target position is X (Y0) axis 0, Y (Y1) axis 0 and Z (Y2) axis 5000, and the lead is 5000, and the radius is 5000 pulse in radius mode, and the synthesis frequency is 1000.{{id name="_Toc24071"/}}{{id name="_Toc17235"/}}{{id name="_Toc1369"/}}{{id name="_Toc21558"/}}{{id name="_Toc23998"/}}{{id name="_Toc21982"/}}{{id name="_Toc6785"/}}{{id name="_Toc22083"/}}{{id name="_Toc31780"/}}{{id name="_Toc5703"/}}
2139 2139  
... ... @@ -2283,7 +2283,7 @@
2283 2283  When the flag bit is [1: pulse sending stop immediately], that is, pulse sending stops immediately without acceleration or deceleration. This flag is not affected by the scan cycle.
2284 2284  
2285 2285  (% style="text-align:center" %)
2286 -[[image:08_html_bb07ddcb0a440df2.gif||height="293" width="700" class="img-thumbnail"]]
2278 +[[image:08_html_bb07ddcb0a440df2.gif||class="img-thumbnail" height="293" width="700"]]
2287 2287  
2288 2288  **(9) Not scanned**
2289 2289  
... ... @@ -2534,7 +2534,7 @@
2534 2534  [1: Stop immediately]: Stop immediately after receiving the stop signal without decelerating movement.
2535 2535  
2536 2536  (% style="text-align:center" %)
2537 -[[image:08_html_c616dcb4f3f0f698.gif||height="288" width="700" class="img-thumbnail"]]
2529 +[[image:08_html_c616dcb4f3f0f698.gif||class="img-thumbnail" height="288" width="700"]]
2538 2538  
2539 2539  **(8) Direction delay**
2540 2540  
... ... @@ -2547,7 +2547,7 @@
2547 2547  |Direction delay|SD905|SD965|SD1025|SD1085|SD1145|SD1205|SD1265|SD1325
2548 2548  
2549 2549  (% style="text-align:center" %)
2550 -[[image:08_html_2e35a77cf58094fa.gif||height="466" width="700" class="img-thumbnail"]]
2542 +[[image:08_html_2e35a77cf58094fa.gif||class="img-thumbnail" height="466" width="700"]]
2551 2551  
2552 2552  **(9) External start signal**
2553 2553  
... ... @@ -2579,12 +2579,12 @@
2579 2579  ①Reachable frequency
2580 2580  
2581 2581  (% style="text-align:center" %)
2582 -[[image:08_html_e260ba033ed851bb.gif||height="366" width="700" class="img-thumbnail"]]
2574 +[[image:08_html_e260ba033ed851bb.gif||class="img-thumbnail" height="366" width="700"]]
2583 2583  
2584 2584  ②Unreachable frequency
2585 2585  
2586 2586  (% style="text-align:center" %)
2587 -[[image:08_html_54e112fa5aeba863.gif||height="386" width="700" class="img-thumbnail"]]
2579 +[[image:08_html_54e112fa5aeba863.gif||class="img-thumbnail" height="386" width="700"]]
2588 2588  
2589 2589  2) Modify the number of pulses:
2590 2590  
... ... @@ -2591,12 +2591,12 @@
2591 2591  ①Modify to the number of reachable pulses
2592 2592  
2593 2593  (% style="text-align:center" %)
2594 -[[image:08_html_f7207d642325c29f.gif||height="282" width="700" class="img-thumbnail"]]
2586 +[[image:08_html_f7207d642325c29f.gif||class="img-thumbnail" height="282" width="700"]]
2595 2595  
2596 2596  ②Modify to the number of unreachable pulses (only support instructions with direction. If there is no direction, stop pulse sending)
2597 2597  
2598 2598  (% style="text-align:center" %)
2599 -[[image:08_html_b73c1c8f2b27e562.gif||height="322" width="700" class="img-thumbnail"]]
2591 +[[image:08_html_b73c1c8f2b27e562.gif||class="img-thumbnail" height="322" width="700"]]
2600 2600  
2601 2601  **{{id name="OLE_LINK371"/}}(12) The number of sent pulses is out of range**
2602 2602  
... ... @@ -2653,17 +2653,17 @@
2653 2653  Time-minute ladder acceleration and deceleration
2654 2654  
2655 2655  (% style="text-align:center" %)
2656 -[[image:08_html_4649b9d5dd0f0a90.gif||height="330" width="700" class="img-thumbnail"]]
2648 +[[image:08_html_4649b9d5dd0f0a90.gif||class="img-thumbnail" height="330" width="700"]]
2657 2657  
2658 2658  Time-minute S-type acceleration and deceleration
2659 2659  
2660 2660  (% style="text-align:center" %)
2661 -[[image:08_html_27806ce2da3a3ef0.gif||height="319" width="700" class="img-thumbnail"]]
2653 +[[image:08_html_27806ce2da3a3ef0.gif||class="img-thumbnail" height="319" width="700"]]
2662 2662  
2663 2663  The following figure shows the changes of each parameter
2664 2664  
2665 2665  (% style="text-align:center" %)
2666 -[[image:08_html_7e62d35d88cbe966.gif||height="614" width="400" class="img-thumbnail"]]
2658 +[[image:08_html_7e62d35d88cbe966.gif||class="img-thumbnail" height="614" width="400"]]
2667 2667  
2668 2668  **✎Note: **When the frequency is modified during the operation, acceleration would accelerate again from zero. There will be discontinuous acceleration.
2669 2669  
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