二手 TERADYNE / EAGLE ETS 364 #9027188 待售

看起來這件物品已經賣了。檢查下面的類似產品或與我們聯系,我們經驗豐富的團隊將為您找到它。

ID: 9027188
Tester ESMO manipulator Primary Digital Card Cage 1 THIB-PRI 2 QTMU 0-3 3 4 5 CBIT-64 6 MCU 7 ISO-COM 64 8 9 10 11 12 13 14 Primary FR Chassis 0 SPU-100 1 2 APU-12 96-107 3 0-7 4 APU-12 36-47 5 6 APU-12 72-83 7 8 SPU-100 9 10 APU-12 84-95 11 12 APU-12 24-35 13 14 APU-12 12-23 15 16 QMS 0-1 17 QMS 2-3 18 QMS 4-5 19 QMS 6-7 20 SPU-100 21 22 SPU-100 23 24 SPU-100 25 26 APU-12 108-119 48-55 27 28 APU-12 60-71 56-63 29 30 APU-12 48-59 31 32 SPU-100 33 34 APU-12 0-11 35 36 37 38 39 `Test head address \0xD000 ////////////////////////////////////////////////////////////////////////////// // Valid Test Head Types: // // 500D, 564, 300, 200, BT2000, 600, 364 // ////////////////////////////////////////////////////////////////////////////// Test head type: \364 Tester Maximum Voltage \maxv \1000 ////////////////////////////////////////////////////////////////////////////// //NOTE: // // All examples use the forward slash '/' instead of the other slash. // // This is so that backward compatibility is maintained. // // // // If you copy the example, please change the forward slash '/' to the // // other slash. // // // ////////////////////////////////////////////////////////////////////////////// // // // Iso-comm Position Mapping Syntax: // // // // Place the logical position number of the floating resource in the // // 'pos' field of the line corresponding to the actual Iso-comm channel. // // If a line is missing or the 'pos' field is left blank, the position // // defaults to direct mapping. // // // // Example: // // // // Iso-comm Channel #0 /icom0 /pos<num> // // // // where: <num> is the logical icom position, 0 to 255 // // // ////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////// // // // Primary Isocomm Card Cage... // // // ////////////////////////////////////////////////////////////////////////////// Iso-comm Channel #0 \icom0 \pos82 Iso-comm Channel #1 \icom1 \pos87 Iso-comm Channel #2 \icom2 \pos0 Iso-comm Channel #3 \icom3 \pos1 Iso-comm Channel #4 \icom4 \pos4 Iso-comm Channel #5 \icom5 \pos5 Iso-comm Channel #6 \icom6 \pos8 Iso-comm Channel #7 \icom7 \pos9 Iso-comm Channel #8 \icom8 \pos2 Iso-comm Channel #9 \icom9 \pos3 Iso-comm Channel #10 \icom10 \pos6 Iso-comm Channel #11 \icom11 \pos7 Iso-comm Channel #12 \icom12 \pos10 Iso-comm Channel #13 \icom13 \pos11 Iso-comm Channel #14 \icom14 \pos14 Iso-comm Channel #15 \icom15 \pos15 Iso-comm Channel #16 \icom16 \pos12 Iso-comm Channel #17 \icom17 \pos13 Iso-comm Channel #18 \icom18 \pos16 Iso-comm Channel #19 \icom19 \pos17 Iso-comm Channel #20 \icom20 \pos20 Iso-comm Channel #21 \icom21 \pos21 Iso-comm Channel #22 \icom22 \pos24 Iso-comm Channel #23 \icom23 \pos25 Iso-comm Channel #24 \icom24 \pos88 Iso-comm Channel #25 \icom25 \pos89 Iso-comm Channel #26 \icom26 \pos90 Iso-comm Channel #27 \icom27 \pos91 Iso-comm Channel #28 \icom28 \pos18 Iso-comm Channel #29 \icom29 \pos19 Iso-comm Channel #30 \icom30 \pos22 Iso-comm Channel #31 \icom31 \pos23 // Next 16 positions are used by 64-channel ISO-COMM boards. Iso-comm Channel #32 \icom32 \pos96 Iso-comm Channel #33 \icom33 \pos97 Iso-comm Channel #34 \icom34 \pos98 Iso-comm Channel #35 \icom35 \pos99 Iso-comm Channel #36 \icom36 \pos100 Iso-comm Channel #37 \icom37 \pos101 Iso-comm Channel #38 \icom38 \pos102 Iso-comm Channel #39 \icom39 \pos103 Iso-comm Channel #40 \icom40 \pos104 Iso-comm Channel #41 \icom41 \pos105 Iso-comm Channel #42 \icom42 \pos106 Iso-comm Channel #43 \icom43 \pos107 Iso-comm Channel #44 \icom44 \pos108 Iso-comm Channel #45 \icom45 \pos109 Iso-comm Channel #46 \icom46 \pos110 Iso-comm Channel #47 \icom47 \pos111 Iso-comm Channel #48 \icom48 \pos28 Iso-comm Channel #49 \icom49 \pos29 Iso-comm Channel #50 \icom50 \pos32 Iso-comm Channel #51 \icom51 \pos33 Iso-comm Channel #52 \icom52 \pos36 Iso-comm Channel #53 \icom53 \pos37 Iso-comm Channel #54 \icom54 \pos80 Iso-comm Channel #55 \icom55 \pos81 Iso-comm Channel #56 \icom56 \pos26 Iso-comm Channel #57 \icom57 \pos27 Iso-comm Channel #58 \icom58 \pos30 Iso-comm Channel #59 \icom59 \pos31 Iso-comm Channel #60 \icom60 \pos34 Iso-comm Channel #61 \icom61 \pos35 Iso-comm Channel #62 \icom62 \pos38 Iso-comm Channel #63 \icom63 \pos39 ////////////////////////////////////////////////////////////////////////////// // // // APU Pin mapping syntax: // // // // Place the logical (mapped) iso-comm position number of the APUin the // // 'pos' field of the line corresponding to the pin numbers which that // // APU board represents. If a line is missing or the 'pos' field is left // // blank, auto-pin assignments will occur for each APU present. // // // // Example: // // // // APU Pin Numbers 0-7 /apu0 /pos<num> // // // // where: <num> is the logical icom position, 0 to 255 // // // ////////////////////////////////////////////////////////////////////////////// APU Pin Numbers 0-7 \apu0 \ APU Pin Numbers 8-15 \apu8 \ APU Pin Numbers 16-23 \apu16 \ APU Pin Numbers 24-31 \apu24 \ APU Pin Numbers 32-39 \apu32 \ APU Pin Numbers 40-47 \apu40 \ APU Pin Numbers 48-55 \apu48 \ APU Pin Numbers 56-63 \apu56 \ APU Pin Numbers 64-71 \apu64 \ APU Pin Numbers 72-79 \apu72 \ APU Pin Numbers 80-87 \apu80 \ APU Pin Numbers 88-95 \apu88 \ APU Pin Numbers 96-103 \apu96 \ APU Pin Numbers 104-111 \apu104 \ APU Pin Numbers 112-119 \apu112 \ APU Pin Numbers 120-127 \apu120 \ APU Pin Numbers 128-135 \apu128 \ APU Pin Numbers 136-143 \apu136 \ APU Pin Numbers 144-151 \apu144 \ APU Pin Numbers 152-159 \apu152 \ APU Pin Numbers 160-167 \apu160 \ APU Pin Numbers 168-175 \apu168 \ APU Pin Numbers 176-183 \apu176 \ APU Pin Numbers 184-191 \apu184 \ APU Pin Numbers 192-199 \apu192 \ APU Pin Numbers 200-207 \apu200 \ APU Pin Numbers 208-215 \apu208 \ APU Pin Numbers 216-223 \apu216 \ APU Pin Numbers 224-231 \apu224 \ APU Pin Numbers 232-239 \apu232 \ APU Pin Numbers 240-247 \apu240 \ APU Pin Numbers 248-255 \apu248 \ ////////////////////////////////////////////////////////////////////////////// // // // APU-12 Pin mapping syntax: // // // // Place the logical(mapped) odd iso-comm position number of the APU-12 in// // the 'pos' field of the line corresponding to the pin numbers which that// // APU-12 board represents. If a line is missing or the 'pos' field is // // left blank, auto-pin assignments will occur for each APU-12 present. // // // // Example: // // // // APU-12 Pin Numbers 0-11 /apu12-pin0 /pos<num> // // where: <num> is the logical icom position, 0 to 255 // // // ////////////////////////////////////////////////////////////////////////////// APU-12 Pin Numbers 0-11 \apu12-pin0 \pos35 APU-12 Pin Numbers 12-23 \apu12-pin12 \pos15 APU-12 Pin Numbers 24-35 \apu12-pin24 \pos13 APU-12 Pin Numbers 36-47 \apu12-pin36 \pos5 APU-12 Pin Numbers 48-59 \apu12-pin48 \pos31 APU-12 Pin Numbers 60-71 \apu12-pin60 \pos29 APU-12 Pin Numbers 72-83 \apu12-pin72 \pos7 APU-12 Pin Numbers 84-95 \apu12-pin84 \pos11 APU-12 Pin Numbers 96-107 \apu12-pin96 \pos3 APU-12 Pin Numbers 108-119 \apu12-pin108 \pos27 APU-12 Pin Numbers 120-131 \apu12-pin120 \ APU-12 Pin Numbers 132-143 \apu12-pin132 \ APU-12 Pin Numbers 144-155 \apu12-pin144 \ APU-12 Pin Numbers 156-167 \apu12-pin156 \ APU-12 Pin Numbers 168-179 \apu12-pin168 \ APU-12 Pin Numbers 180-191 \apu12-pin180 \ APU-12 Pin Numbers 192-203 \apu12-pin192 \ APU-12 Pin Numbers 204-215 \apu12-pin204 \ APU-12 Pin Numbers 216-227 \apu12-pin216 \ APU-12 Pin Numbers 228-239 \apu12-pin228 \ APU-12 Pin Numbers 240-251 \apu12-pin240 \ : : : : : APU-12 Pin Numbers 468-479 \apu12-pin468 \ ////////////////////////////////////////////////////////////////////////////// // // // QMS Pin mapping syntax: // // // // Place the logical (mapped) iso-comm position number of the QMS in the // // 'pos' field of the line corresponding to the pin numbers which that QMS // // icom num represents. If a line is missing or the 'pos' field is left // // blank, auto-pin assignments will occur for each QMS pin present. // // // // Example: // // // // QMS Pin Numbers 8-9 /qms8 /pos<num> // // // // where: <num> is the logical icom position, 0 to 255 // // // ////////////////////////////////////////////////////////////////////////////// QMS Pin Numbers 0-1 \qms0 \pos16 QMS Pin Numbers 2-3 \qms2 \pos17 QMS Pin Numbers 4-5 \qms4 \pos18 QMS Pin Numbers 6-7 \qms6 \pos19 QMS Pin Numbers 8-9 \qms8 \ QMS Pin Numbers 10-11 \qms10 \ QMS Pin Numbers 12-13 \qms12 \ QMS Pin Numbers 14-15 \qms14 \ QMS Pin Numbers 16-17 \qms16 \ QMS Pin Numbers 18-19 \qms18 \ QMS Pin Numbers 20-21 \qms20 \ QMS Pin Numbers 22-23 \qms22 \ QMS Pin Numbers 24-25 \qms24 \ QMS Pin Numbers 26-27 \qms26 \ QMS Pin Numbers 28-29 \qms28 \ QMS Pin Numbers 30-31 \qms30 \ : : : : : QMS Pin Numbers 124-125 \qms124 \ QMS Pin Numbers 126-127 \qms126 \ ////////////////////////////////////////////////////////////////////////////// // // // QHSU Pin mapping syntax: // // // // Place the logical (mapped) iso-comm position number of the QHSU in the // // 'pos' field of the line corresponding to the pin numbers which that QHSU// // icom num represents. If a line is missing or the 'pos' field is left // // blank, auto-pin assignments will occur for each QHSU pin present. // // // // Example: // // // // QHSU Pin Numbers 8-9 /qhsu8 /pos<num> // // // // where: <num> is the logical icom position, 0 to 255 // // // ////////////////////////////////////////////////////////////////////////////// QHSU Pin Numbers 0-1 \qhsu0 \ QHSU Pin Numbers 2-3 \qhsu2 \ QHSU Pin Numbers 4-5 \qhsu4 \ QHSU Pin Numbers 6-7 \qhsu6 \ QHSU Pin Numbers 8-9 \qhsu8 \ QHSU Pin Numbers 10-11 \qhsu10 \ QHSU Pin Numbers 12-13 \qhsu12 \ QHSU Pin Numbers 14-15 \qhsu14 \ QHSU Pin Numbers 16-17 \qhsu16 \ QHSU Pin Numbers 18-19 \qhsu18 \ QHSU Pin Numbers 20-21 \qhsu20 \ QHSU Pin Numbers 22-23 \qhsu22 \ QHSU Pin Numbers 24-25 \qhsu24 \ QHSU Pin Numbers 26-27 \qhsu26 \ QHSU Pin Numbers 28-29 \qhsu28 \ QHSU Pin Numbers 30-31 \qhsu30 \ : : : : : : : : : : : : QHSU Pin Numbers 252-253 \qhsu252 \ QHSU Pin Numbers 254-255 \qhsu254 \ ////////////////////////////////////////////////////////////////////////////// // // // 8x8 Matrix Resource/Channel mapping syntax: // // // // Place the logical (mapped) iso-comm position number of the 8x8 Matrix // // in the 'pos' field of the line corresponding to the Resource/Channel // // numbers which that 8x8 Matrix board represents. If a line is missing // // or the 'pos' field is left blank, resource/channel number assignments // // will occur automatically for each 8x8 Matrix present. // // // // Example: // // // // Matrix Res/Chan Numbers 0-7 /mat0 /pos<num> // // // // where: <num> is the logical icom position, 0 to 255 // // // ////////////////////////////////////////////////////////////////////////////// Matrix Res/Chan Numbers 0-7 \mat0 \ Matrix Res/Chan Numbers 8-15 \mat8 \ Matrix Res/Chan Numbers 16-23 \mat16 \ Matrix Res/Chan Numbers 24-31 \mat24 \ Matrix Res/Chan Numbers 32-39 \mat32 \ Matrix Res/Chan Numbers 40-47 \mat40 \ Matrix Res/Chan Numbers 48-55 \mat48 \ Matrix Res/Chan Numbers 56-63 \mat56 \ Matrix Res/Chan Numbers 64-71 \mat64 \ Matrix Res/Chan Numbers 72-79 \mat72 \ Matrix Res/Chan Numbers 80-87 \mat80 \ Matrix Res/Chan Numbers 88-95 \mat88 \ Matrix Res/Chan Numbers 96-103 \mat96 \ Matrix Res/Chan Numbers 104-111 \mat104 \ Matrix Res/Chan Numbers 112-119 \mat112 \ Matrix Res/Chan Numbers 120-127 \mat120 \ Matrix Res/Chan Numbers 128-135 \mat128 \ Matrix Res/Chan Numbers 136-143 \mat136 \ Matrix Res/Chan Numbers 144-151 \mat144 \ Matrix Res/Chan Numbers 152-159 \mat152 \ Matrix Res/Chan Numbers 160-167 \mat160 \ Matrix Res/Chan Numbers 168-175 \mat168 \ Matrix Res/Chan Numbers 176-183 \mat176 \ Matrix Res/Chan Numbers 184-191 \mat184 \ Matrix Res/Chan Numbers 192-199 \mat192 \ Matrix Res/Chan Numbers 200-207 \mat200 \ Matrix Res/Chan Numbers 208-215 \mat208 \ Matrix Res/Chan Numbers 216-223 \mat216 \ Matrix Res/Chan Numbers 224-231 \mat224 \ Matrix Res/Chan Numbers 232-239 \mat232 \ Matrix Res/Chan Numbers 240-247 \mat240 \ Matrix Res/Chan Numbers 248-255 \mat248 \ ////////////////////////////////////////////////////////////////////////////// // // // Internal Cbit Wiring syntax: // // // // Use this section to specify Internal Cbits that are hard wired to a // // resource and cannot be toggled during diagnostics. Any Internal Cbits // // specified in this section will be skipped during Cbit diagnostics. // // The second field can be any user-defined string. // // If a line is missing or the second field is left blank, the Internal // // Cbit will be tested normally during diagnostics. // // // // Example: // // // // Internal Cbit Wiring #0 \icbit0 \RF Cal Board // // // ////////////////////////////////////////////////////////////////////////////// Internal Cbit Wiring #0 \icbit0 \ Internal Cbit Wiring #1 \icbit1 \ Internal Cbit Wiring #2 \icbit2 \ : : : : : Internal Cbit Wiring #31 \icbit31 \ ////////////////////////////////////////////////////////////////////////////// // // // RF3000 -DOWNCONVERTER to QMS Connection: // // // // Place here the QMS pin that connects to the downconverter output // // // // Valid qms<pin>'s are: 0 - 127 // // Example: // // // // RF3000 DOWNCONV /rf3dwncnv /qms4 // // // ////////////////////////////////////////////////////////////////////////////// RF3000 DOWNCONV \rf3dwncnv \ ////////////////////////////////////////////////////////////////////////////// // // // DUAL RF3000 -DOWNCONVERTER to QMS Connections: // // // // Place here the QMS pin that connects to the downconverter output // // // // Valid qms<pin>'s are: 0 - 127 // // Example: // // // // RF3000 DOWNCONV /drf3dwncnv-0 /qms4 // // RF3000 DOWNCONV /drf3dwncnv-1 /qms5 // // // ////////////////////////////////////////////////////////////////////////////// RF3000 DOWNCONV \drf3dwncnv-0 \ RF3000 DOWNCONV \drf3dwncnv-1 \ ////////////////////////////////////////////////////////////////////////////// // // // RF6000 CONFIGURATION: // // I- Iso-comm position assignment // // II- RF6000 QDC to QHSU connection (Direct or Multiplexed) // // III- SMIQ to QHSU (I/Q) connections // // // // // // Assign two consecutive Iso-comm positions from the // // "MAINFRAME CARD CAGE" group to the RF6000 resources. // // // // Iso-comm assignment Example: // // // // Iso-comm base Resource \ires88 \RF6-SRC // // Iso-comm base Resource \ires89 \RF6-MEAS // // // // // // DIRECT QDC-QHSU CONNECTION EXAMPLE: // // // // rf6 qdc to qhsu connection \rf6qdc-0_0 \qhsu-rf0 // // rf6 qdc to qhsu connection \rf6qdc-0_1 \qhsu-rf1 // // rf6 qdc to qhsu connection \rf6qdc-0_2 \qhsu-rf2 // // rf6 qdc to qhsu connection \rf6qdc-0_3 \qhsu-rf3 // // // // rf6 qdc to qhsu connection \rf6qdc-1_0 \qhsu-rf4 // // rf6 qdc to qhsu connection \rf6qdc-1_1 \qhsu-rf5 // // rf6 qdc to qhsu connection \rf6qdc-1_2 \qhsu-rf6 // // rf6 qdc to qhsu connection \rf6qdc-1_3 \qhsu-rf7 // // // // MUXED QDC-QHSU CONNECTION EXAMPLE: // // // // rf6 qdc to qhsu connection \rf6qdc-mux-0_0 \qhsu-rf0 // // rf6 qdc to qhsu connection \rf6qdc-mux-0_1 \qhsu-rf1 // // rf6 qdc to qhsu connection \rf6qdc-mux-0_2 \qhsu-rf2 // // rf6 qdc to qhsu connection \rf6qdc-mux-0_3 \qhsu-rf3 // // // // rf6 qdc to qhsu connection \rf6qdc-mux-1_0 \qhsu-rf0 // // rf6 qdc to qhsu connection \rf6qdc-mux-1_1 \qhsu-rf1 // // rf6 qdc to qhsu connection \rf6qdc-mux-1_2 \qhsu-rf2 // // rf6 qdc to qhsu connection \rf6qdc-mux-1_3 \qhsu-rf3 // // // // // // SMIQ QHSU (I/Q) CONNECTION EXAMPLE: // // rf6 iq to qhsu connection \rf6src-0_I \qhsu0 // // rf6 iq to qhsu connection \rf6src-0_Q \qhsu1 // // rf6 iq to qhsu connection \rf6src-1_I \qhsu2 // // rf6 iq to qhsu connection \rf6src-1_Q \qhsu3 // // // ////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////// // // // GPIB mapping syntax: // // // // Place here the GPIB addresses versus system resource mapping // // // // Valid GPIB addresses : gpib-0 to gpib-30 // // Valid resource keywords are: // // RS0, RS1, RS2, LO // // // // Example: // // // // GPIB Address /gpib-28 /RS2 // // // // Please consult ets\inc\gpib500d.h to avoid gpib address conflicts // // // // The following table shows the proper RF connections: // // RS0 -> SRC#0 // // RS1 -> SRC#1 // // RS2 -> SRC#2/TS PORT // // LO -> LO // ////////////////////////////////////////////////////////////////////////////// GPIB Address \gpib-28 \ ////////////////////////////////////////////////////////////////////////////// // // // REFCLK GPIB mapping syntax: // // // // Place here the type-model and GPIB addresses versus REFCLK system // // resource mapping. // // // // Valid types: PTS-040, PTS-120, PTS-160, PTS-250, PTS-500, PTS-620 // // PTS1000 // // Valid GPIB addresses : gpib-0 to gpib-30 // // Valid resource keywords are: // // RCLK0, RCLK1 , RCLK2, RCLK3 // // // // Example: // // // // GPIB Address \gpib-24 \RCLK0 PTS-160 // // // // Please consult ets\inc\gpib500d.h to avoid gpib address conflicts // // // ////////////////////////////////////////////////////////////////////////////// GPIB Address \gpib-24 \ ////////////////////////////////////////////////////////////////////////////// // DPS Emulation syntax: // // // // This section allows the user to use either an SPU-100 or an FSS to // // emulate a DPS in an application (without re-compiling the app). // // Place the logical (mapped) iso-comm position number of either the // // SPU-100 or the FSS2000 in the 'pos' field of the line corresponding to // // the specific DPS Power Supply. The utilities will figure out which // // resource is actually at the position number. // // A translator board does need to be in place in order to physically // // route the FSS or SPU-100 to the DPS Power Supply pins. // // // // Example: The SPU-100 in position 23 will emulate the DPS Power Supply 1 // // // // DPS Power Supply 1 \dpsps1 \pos23 // // // ////////////////////////////////////////////////////////////////////////////// DPS Power Supply 0 \dpsps0 \ DPS Power Supply 1 \dpsps1 \ DPS Power Supply 2 \dpsps2 \ DPS Load Power Supply 0 \dpsldps0 \ DPS Load Power Supply 1 \dpsldps1 \ ////////////////////////////////////////////////////////////////////////////// // // // Iso-comm connections to the 'Iso-comm Via FR Bus' Board // // // // Place the logical position numbers of the Iso-comm channels connected // // to the IVFR board in the 'pos' fields below. // // // // If these lines are missing or ALL 'pos' fields are left blank, the // // IVFR board will not be used even though it may be present. // // // // Example: // // // // IVFR Section #0 \ivfr0 \pos<num> // // // // where: <num> is the logical icom position, 0 to 255 connect
TERADYNE/EAGLE ETS 364是一款高端的最終測試設備,為大批量制造環境提供了靈活性、準確性和可靠性。它旨在提供自動缺陷篩選、測試診斷、產量分析和資源管理。EAGLE ETS364是制造商希望在最終測試過程中提高產量和降低成本的理想解決方案。TERADYNE ETS-364設計用於測試從離散組件到復雜系統的各種設備。其靈活的體系結構允許廣泛的測試策略,包括嵌入式診斷、在線測試部署和動態重新配置功能。它完全符合IEEE 1149.1和1149.4測試標準,支持自動電路內測試和JTAG測試設備特性。TERADYNE ETS 364提供了一個高級診斷庫,該庫具有高級算法和參數,旨在檢測一系列設備性能異常。該系統配備了強大的測試分析工具,提供圖形測試結果分析、綜合統計報告和可導出數據。該單元提供端到端制造支持,從設置和測試執行到缺陷診斷和修復。除了強大的測試功能外,ETS-364還提供高速數據采集和數字刺激應用。其先進的信號處理技術大大縮短了總測試時間,從而實現了快速、高效的生產周期。它還為各種設備和操作系統提供多種API和「即插即用」硬件支持。對於希望提高測試產量和降低最終測試機成本的制造商來說,ETS364是一個可靠且經濟高效的解決方案。它的高級診斷庫、測試分析工具和數據采集功能在單個平臺中提供了完整的設備測試功能。該工具易於集成到現有系統中,並且能夠在不同的設備上快速運行各種測試。對於希望改進測試策略和縮短上市時間的制造商來說,ETS 364是一個理想的解決方案。
還沒有評論