AMIS-49200EVB AMIS-492x0 Fieldbus MAU Evaluation Board User's Manual http://onsemi.com EVAL BOARD USER’S MANUAL Introduction known to pass the Foundation Fieldbus Physical Layer Conformance (Specification FF830, Rev 1.5). The reference design discussed in this document also includes additional flexible sub-circuits not discussed in the AMIS-492x0 data sheet, that help the user optimally fit the AMIS-492x0 to their application. ON Semiconductor offers the AMIS-492x0 Fieldbus Media Access Unit (MAU) as part of an overall industrial network communication solution. Please refer to the AMIS-492x0 data sheet for more information on this integrated circuit. The scope of this user’s manual focuses on a reference design and board that ON Semiconductor also offers its customers, and which satisfies the Foundation Fieldbus H1 or Profibus PA physical layer network requirement. This user’s manual helps the user design in the AMIS-492x0 MAU, by referring to a usable board design Process Sensor Fieldbus Node Description Figure 1 shows a typical, complete node using the AMIS-492x0. RXA Microprocessor, I/O (A/D) Fieldbus or Profibus Link Controller + RXS AMIS−492x0 Fieldbus MAU TXE Discrete Components TXS Fieldbus Segment Connection PFAIL2 PFAIL1 RAM Vo ROM VSHUNT Reference Design in Figure 12 of Data Sheet Figure 1. Complete Fieldbus Device using AMIS-492x0 AMIS-492x0 Fieldbus MAU Reference Design A link controller is placed between a typical microprocessor and the AMIS-492x0 MAU to provide Manchester encoding and decoding of the data to be transmitted or received, respectively. It may be possible to program a high-end microprocessor to handle the Manchester style data stream, but the effort to do so is likely cost prohibitive. One example of a suitable link controller is the UFC100-F1 by Softing/Aniotek, Inc. (http://www.softing.com/home/en/industrial-automation/p roducts/foundation-fieldbus/device-integration/universal-f ield-controller.php?navanchor=3010446) © Semiconductor Components Industries, LLC, 2013 April, 2013 − Rev. 3 ON Semiconductor has developed a reference design for commercial use in a Foundation Fieldbus H1 or Profibus PA application. Figure 12 in the AMIS-492x0 data sheet shows an example of external circuitry required to connect the AMIS-492x0 to an IEC 61158-2 conformant network. That schematic is of a circuit that passed the Foundation Fieldbus Physical Layer Conformance test as specified in Foundation Fieldbus Specification FF830, Rev 1.5. There are many alternative designs and it is beyond the scope of this document to identify all possible 1 Publication Order Number: EVBUM2180/D AMIS−49200EVB as is, often this design can be slightly modified given unique application-related traits. Figure 12 in the AMIS-492x0 data sheet shows a general schematic independent of board layout. Figure 2 shows the AMIS-492x0 reference design that includes extra components to accommodate such application flexibility. This schematic together with PCB build files and a bill of material (BOM) constitute the AMIS-492x0 reference design package which can be found at the link listed in this document’s reference section. The design in Figure 2 also passes the Foundation Fieldbus test (FF830, Rev. 1.5). configurations. We strongly encourage customers to use the ON Semiconductor reference design to provide the most effective application support. Whether or not the ON Semiconductor reference design is used, we recommend that the customer perform their own physical layer board test to ensure conformance. In addition, board layout can alter the behavior of all circuit implementations, even designs that follow the recommended implementation. Fieldbus Foundation (www.fieldbus.org) provides the required test specifications to their membership only. ON Semiconductor cannot provide these specifications to customers. Although the ON Semiconductor reference design in the AMIS-492x0 data sheet passed physical layer conformance Figure 2. AMIS-492x0 Reference Design Schematic • Certain sub-circuits (e.g. voltage dividers) have been Please note the following: • A bridge rectifier was added to interface with the medium. This allows proper, correct operation regardless of polarity hook-up. • Test points are included to provide convenient access to the circuit for development purposes. added to adjust analog (shunt regulator) supply voltage, digital (series regulator) supply voltage, and loop current settings (loop current regulator). Figure 2 shows these components as “TBD” to be adjusted by the customer as needed to modify the design to their application requirements. The “TBD” resistors not installed by default on the reference board are listed in Table 1. http://onsemi.com 2 AMIS−49200EVB divider. In this configuration R24, R10 and R7 are all installed with 0 ohm resistors. R9, R8 and R23 are not populated. To disable the series regulator (e.g. to consume as little power as possible), remove R24, R10 and R7. Install 0 Ohm jumpers in R9 and R23, and leave R8 empty. R9 shorts out the pass transistor so that it cannot turn on. R23 grounds the non-inverting input to the regulator amplifier and forces the output to saturate so that it cannot oscillate. Removing R10 relieves the regulator amplifier output of any possible load. Removing R7 isolates the internal divider. Removing R24 disconnects the series regulator output from the external (digital) rail. Table 1. Components That May Be Modified on the Reference Board Resistor Used to Adjust R12 Shunt regulator voltage R13 Shunt regulator voltage R8 Series regulator voltage R23 Series regulator voltage R22 Loop current Shunt Regulator See Section 4.2.1 and Figure 4 in the AMIS-492x0 data sheet. As assembled the shunt regulator output will be 5.02 V at Pin 8 (SHUNT). This voltage is set by connecting Pin 7 (SHSET) to Pin 6 (SHSETin) via R11 (zero W). This connection connects the internal voltage divider to the shunt regulator amplifier non-inverting input. To set the shunt regulator output to another voltage, remove R11 and install R12 and R13. The shunt regulator voltage can be set in the range of 4.75 V to 6.2 V. The formula for this is: ǒ Ǔ R V SHUNT + V ref @ 1 ) 12 R 13 Loop Current Regulator The value of the loop current is set by the parallel combination of R21 and R22. As shipped, R22 is not installed and R21 = 49.9 kW. This sets the loop current to 10 mA. Decreasing the value of the parallel combination of R21 and R22 increases the loop current. The formula to calculate the value of the loop current is in Equation 3. Customer Board Tips and Suggestions for Production The customer might find the following suggestions helpful in planning for production and/or development: • Use full embedded power and ground planes in a four-layer PCB configuration to reduce the likelihood of noise. The AMIS-492x0 reference board is a two-layer board to ease evaluation and development. • To accommodate board space constraints, you might want to use surface-mount components. The AMIS-492x0 reference board uses a few thru-hole components. • Pin 36 (TXE) and Pin 37 (TXS) are CMOS digital inputs and cannot float. If the board is not connected to a link controller or other circuitry at JP1, TXS (FB_TXS on JP1) must be pulled to VDD, and TXE (FB_TXE on JP1) must be pulled to ground. where V ref + 1.18 V (eq. 1) Series Regulator See Section 4.2.2 and Figure 5 in the AMIS-492x0 data sheet. As assembled the series regulator output will be 3.04 V at Pin 16 (VO). This voltage is set by connecting Pin 13 (SRSET) to Pin 12 (SRSETin) via R7 (zero W). This connection connects the internal voltage divider to the shunt regulator amplifier non-inverting input. Also Pin 14 (SRAO) is connected to Pin 15 (SRTR) via R10 (zero W). This connects the output of the series regulator amplifier to the pass transistor. To set the series regulator output to another voltage, remove R7 and install R8 and R23. The series regulator voltage can be set in the range of 2.85V to 3.5V. The formula for this is: ǒ V O + V ref @ 1 ) Ǔ R8 R 23 where V ref + 1.18 V AMIS-492x0 Evaluation Kit (AMIS-49200EVB) ON Semiconductor provides an evaluation kit that showcases the AMIS-492x0 Fieldbus MAU on-board for real-time demonstration and evaluation. The AMIS-49200EVB kit includes: • Reference board following the schematic in Figure 2, including the AMIS-49200 device. • Connector to aid evaluation of MAU and link controller interface. Please contact your local ON Semiconductor sales representative for AMIS-49200EVB price and availability. (eq. 2) The board as shipped will be configured to have the series regulator operating and set to 3 V using the internal voltage NJƪǒ V drv R 5 Ǔ*V mid @ Ǔƫ @ R ǒ R 21ø22 R 5@(R 3)R ) 21ø22 I loop + Nj NJ 14 * V mid @ ǒ R 21ø22 R 3)R 21ø22 ǓNj R 15 where: Vdrv = 2.5 V, Vmid = 2.0 V, R5 = R3 = 249 kW, R15 = 10 W, R21⎪⎪22 ≤ 49.9 kW http://onsemi.com 3 (eq. 3) AMIS−49200EVB Appendix (A) Component Label Cross Reference The component values in Figure 2 in this document and Figure 12 in the AMIS-492x0 data sheet are differently labeled. For convenience, a cross-reference list is found in Table 2. Table 2. Component Cross-Reference List between Reference Design and Data Sheet Reference Board Data Sheet C1 C5 C2 C6 C3 C9 C4 Reference Board Data Sheet Reference Board Data Sheet D5 D3 R13 N/A Q1 Q2 R14 R11 Q2 Q4 R15 R10 C8 Q3 Q3 R16 R8 C5 C3 Q4 Q1 R17 R7 C6 C1 R1 N/A R18 R4 C7 C2 R2 R1 R19 R6 C8 C4 R3 R2 R20 R5 C9 C11 R4 n/a R21 R3 C10 N/A R5 R12 R22 N/A C11 C10 R6 R9 R23 N/A C12 C7 R7 N/A R24 N/A C13 N/A R8 N/A R25 N/A D1 N/A R9 N/A U2 D1 D2 N/A R10 N/A U2 D2 D3 N/A R11 N/A VAA Vshunt D4 N/A R12 N/A References • AMIS−492x0 Fieldbus MAU Data Sheet; http://www.onsemi.com/pub_link/Collateral/49200−D.PDF • AMIS-492x0 Reference Design Package including schematic, BOM and PCB layout files; http://onsemi.com/PowerSolutions/product.do?id=AMIS−49200−XTD Company or Products Inquiry For more information about ON Semiconductor’s products or services visit our Web site at http://onsemi.com. ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). 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