Occasion TERADYNE / EAGLE ETS 364 #9027188 à vendre en France

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