Agilent AEAT-84AD 14/12 Bit Multi-turn Encoder Module Data Sheet Description Specifications The AEAT-84AD provides all functions as an optoelectronicmechanical unit in order to implement, with single turn absolute encoder, an absolute multi-turn encoder with a combined capacity of up to 30 bits at extended temperature. The multi-turn unit is available in the following versions: The unit consists of an IR-LED circuit board, a phototransistor (PT) circuit board, and 6 or 7 gear wheels arranged in between the PCBs. * 12-bit solid shaft * 14-bit solid shaft Features * 16384 (14bits) and 4096 (12bits) revolution count versions * Optical, absolute multi-turn assembly with max. O55 mm and typical height 12.2 mm. * Operating temperatures of -40C to +125C * Mechanical coupling by means of 14 teeth gear pinion with module of 0.3 * Operating speeds up to 12,000 rpm * A 2x4-pole pin strip for power supply and signal Applications * Major component of Multi-turn housed encoder * Cost effective solution for direct integration into OEM systems * Linear positioning system Benefits * No battery or capacitor required for number of revolution counting during power failure * Immediate position detection on power up Package Dimensions Notes: 1. 3rd Angle Projection 2. Dimensions are in millimeters 3. Example of matching connector: MPE GARRY 521 Series, No. BL21-43GGG-008 Figure 1. Package dimensions Block Diagram and Detailed Description In the following descriptions, the I/O pins are enclosed by a box, e.g., MTMUX[2:0]. VCC (+5V) 7x 3 PT's 7x 3 IR's 3 1 of 8-Decoder MTMUX[2:0] 3 x 100K 3 x 4K7 3 x 4K7 3 3 3 MTDAT[2:0] Comparator GND Figure 2. Block Diagram 2 Multiplexing and Position Data Each of the 1:4 reduced 7 coded gear wheels generates a 3-bit code, from which the 14bit Gray code can be generated as position data through V-bit processing. The 3-bit code is identical electrically for all gear wheels, only the projection on the mechanical angle (the revolutions) is different according to the 1:4 divisions. The code and the data bits and V-bits to be generated are shown in the Figure 3 for the gear wheel 1: Shaft Turns 0 1 2 3 4 MSB Singleturn 1. Wheel Turns 0 1 1. MTDAT[0] 1. MTDAT[1] 1. MTDAT[2] Gray Code (generated) Data-Bit1 Data-Bit2 V-Bit2 Figure 3. Multiplexing Diagram for gear wheel 1 The 3-bit codes of the gear wheels 1 to 7 are output on MTDAT[2:0] de-multiplexed with MTMUX[2:0]. Here, the binary value on MTMUX[2:0] corresponds to the gear-wheel number (1 = gear wheel 1, 2 = gear wheel 2, etc.). The configuration is displayed with the value "0." Table 1. Demultiplexing Diagram for all gear wheels Table 1 shows the assignments: Notes: 1. Applicable for AEAx-84AD solid shaft version only 3 Bin/ Dec MTMUX [2:0] MTDAT[2] MTDAT[0] Notes 1 = Solid Shaft 1 3-bit gear wheel 1 3-bit gear wheel 2 to 3-bit gear wheel 7 001 / 1 010 / 2 to 111 / 7 000 / 0 MTDAT[1] always 1 0 = 12 bit 1 = 14 bit Gray code-generation Logic Diagram For the readout schematic of the multi-turn code gears, i.e. with the user's microcontroller, there must be a logical replication of the V-bit multiplexers. This can be done by a bit manipulation or by look up tables. Care needs to be taken with the real time readout conditions. From MTDAT-Demux (Code-Wheel x) 4x MUX2 Cx[2] 0 V2 Y Cx[1] (V-Bit2) 1 S 0 Y The procedure is as follows : 1. The 3 bits ( MTDAT[2:0] ) of each gear (C1[2:0] to C7[2:0]) are continuously de-multiplexed. Thus there are maximal 3 bits x 7gears = 21-bit AEAT-84AD data in parallel. 2. Synchronous to the readout of the single turn absolute encoder, those AEAT-84AD bits (depending on the MSB bit, i.e. SEL-bit, of the single turn encoder) needs to be complemented to the complete Gray code word (cascading). 3. The bit change of the complete Gray code will be synchronized by the single turn absolute encoder and thus electronically eliminating gear play. The logic diagram for ONE gear is shown in the following diagram (V-bit-Multiplexer), Figure 4. (Data-Bit2) 1S XOR 0 Y Cx[0] 1 S 0 Y 1S SEL SEL Cx[0] Cx[1] Cx[2] D1 D2 V2 0 0 1 1 0 1 1 1 0 0 0 1 0 0 0 0 0 0 1 1 0 0 0 0 0 0 0 0 0 0 1 1 1 0 0 0 1 1 1 1 0 0 0 1 1 1 0 0 1 1 1 1 0 0 0 0 0 0 1 1 0 1 1 1 1 1 1 0 1 1 1 1 0 0 1 1 1 1 1 1 1 1 1 1 0 0 1 1 1 0 0 0 0 0 0 0 1 1 1 0 1 1 0 0 0 0 0 0 1 1 1 1 Figure 4. Logic Diagram and Truth Table for one of the gear wheels 4 D2 D1 (Data-Bit1) The Figure 5 shows the cascading of the V-bitMultiplexer of all gear wheels. The outputs are the 14bits Gray code in parallel. V-bit-Multiplexer Cascade C7[2] Demuxed Code-Wheel 7 C7[1] C7[0] Cx[2] V2 Cx[1] D2 Cx[0] D1 Gray-Bit14 Gray-Bit13 (MSB for 14Bit) Gray-Bit12 SEL The MSB of the complete code is dependant on the total resolution of the system. It can be used in steps of 2 bits (14Bit,12Bit,...etc). Unused higher bits should be masked to logical zero. With the data-multiplexer IC version of the multi-turn encoder module, the data multiplexer IC will perform the complete driving and data processing of the encoder units while maintaining all time constraints. There is an IC available to combine both the AEAS-7x00 13/16bit single turn component and the AEAx-84AD 12/14bit multiturn module into onesingle powerful multi-turn absolute encoder. This onestop solution enables the design of a high-end absolute encoder with minimum component count at integration level. Figure 6 shows an application example of integration of single-turn absolute encoder and multiturn module using MUIC. Note: To simplify the synchronization with single-turn absolute encoder(e.g. AEAS-7000), the total solution has been embedded into a single chip MUIC. Please refer to the Ordering Information for this device. 5 C6[2] Demuxed Code-Wheel 6 C6[1] C6[0] Cx[2] V2 Cx[1] D2 Cx[0] D1 Gray-Bit12 Gray-Bit11 (MSB for 12Bit) Gray-Bit10 SEL C5[2] Demuxed Code-Wheel 5 C5[1] C5[0] Cx[2] V2 Cx[1] D2 Cx[0] D1 Gray-Bit9 Gray-Bit8 SEL C2[2] Demuxed Code-Wheel 2 C2[1] C2[0] Cx[2] V2 Cx[1] D2 Cx[0] D1 Gray-Bit3 Gray-Bit2 SEL C1[2] Demuxed Code-Wheel 1 C1[1] C1[0] Cx[2] V2 Cx[1] D2 Cx[0] D1 SEL Sample AEAS-7000 MSB Figure 5. The cascading of V-bit-Multiplexer of all gear wheels Gray-Bit1 Gray-Bit0 Application Example of Multiturn Absolute Encoder Figure 6. Application example of integration of single-turn absolute encoder module and multiturn module using MUIC. Device Selection Guide 1 Part Number Resolution Operating Temperature (C) Output Format DC Supply Voltage (V) AEAT-84AD-LBSC0 12 bit -40 to 125 Multiplexed 5.0 to 5.5 AEAT-84AD-LBSF0 -40 to 125 Multiplexed 5.0 to 5.5 14 bit Notes: 1. SSI interface is enabled through MUIC. Please refer to Ordering Information for MUIC. 6 Absolute Maximum Ratings 1, 2 Parameter Symbol Limits Units DC Supply Voltage VCC -0.3 to + 6.0 V Input Voltage Vi -0.5 to 5.5 V Output Voltage Vo -0.5 to +VCC +0.5 V Moisture Level (Non-Condensing) %RH 85 % Encoder Shaft Speed SRPM Max 12000 rpm Storage Temperature Tstg -40 to 125 C Notes: 1. Stresses greater than those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is stress rating only and functional operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. 2. Exposure to absolute maximum rating conditions for extended periods may affect reliability. 3. This device meets the ESD ratings of the IEC61000-4-2 Level 2 (4KV). Recommended Operating Conditions Parameter Symbol Values Units DC Supply Voltage VCC +5.0 / +5.5 V Ambient Temperature Tamb -40 to +125 C Multiplex Read Delay tDMUXRD 64 s Encoder Shaft Speed SRPM 10000 or below rpm Notes 1 Notes: 1. As unique coded gear-wheels techniques are implemented to generate unambigous positional information, the interactions between these highly wear- resistant gear wheels are subjected to mechanical wear and tear. DC Characteristics DC Characteristics over Recommended Operating Range, typical at 25 C Values Parameter Symbol Condition Min MTDAT[2:0] Output High Voltage (10k Pull-up) VOH IOH = -50A 4.0 MTDAT[2:0] Output Low Voltage (4k7 Series-R) VOL IOL = -50A Input High Voltage VIH VCC=5.0V VCC=5.5V Input Low Voltage VIL MTMUX[2:0] Input Current, VIN-VCC or 0V IIL /IIH VCC Supply Current ICC 7 100k Pull-down Typ. Max Units V 0.4 3.2 3.9 V V -10 68 0.8 V 100 A 76 mA Timing Characteristics Timing Characteristics over Recommended Operating Range, typical at 25 C Values Parameter Symbol Condition Input Transition Rise/Fall Time tR /tF 0.8V/3.0V Multiplex Read Delay tDMUXRD Encoder Shaft Speed SRPM MTMUX[2:0] old value Min Typ. Max 12000 Max Units 500 ns 64 s 12000 rpm new value t DMUXRD MTDAT[2:0] old value new value Figure 7. Timing Characteristics of MTMUX[2:0] and MTDAT[2:0] Electrical Connections Pin Description 1 GND 2 MTDAT2 3 MTDAT1 4 MTDAT0 5 MTMUX2 6 MTMUX1 7 MTMUX0 8 VCC See Detail 1 7 3 8 6 1 4 Detail 1 Figure 8. Pin Configuration 8 5 2 Application Note The encoder is mechanically fixed by means of holes in adapters, which accommodate M3 threads. The encoder has 2 adapters for attaching in a 3 x 120 and 4 x 90 arrangement. For details, please refer to the mechanical drawings in Figure 1. The mechanical coupling of the encoder shaft is realised by means of gear pinion with a module of 0.3, 14 teeth. The zero positions of the coupling wheels are locked with a plastic plug for alignment to the single turn absolute encoder, with the coupling wheel being able to compensate for an angle error of about +/-7. Plastic plug is removed upon integration with gearwheel. The electrical connection is realized by means of a 2x4 pin strip (1.27mm pitch), which is plugged into a corresponding female connector. The encoder is attached with a plastic plug that locks the absolute zero position. During the mating of the gear pinion and the encoder coupling gear wheel it may be necessary to align the teeth of the gears for proper matching. The plastic plug can be removed upon integration with the gear wheel. Zero position of coupling wheel Plastic plug Pinion, module 0.3, 14 teeth Figure 9. Mechanical coupling with Multiturn Encoder Module 9 Ordering Information AEAT-84AD-LBSC0 multi-turn, -40 to +125oC, solid shaft, serial, 12 bit AEAT-84AD-LBSF0 multi-turn, -40 to +125oC, solid shaft, serial, 14 bit Ordering information for MUIC: MUIC1-V0A leaded, extended temperature range +125C MUIC1-V0A-X79 lead-free, extended temperature range +125C Note: The manufacturer contact for the above MUIC part numbers is as follows: OPTOLAB Microsystems AG Konrad-Zuse-Str.14 DE-99099 Erfurt / Germany Phone: +49-361-55144-0 Fax: +49-361-55144-50 Email: agilent@optolab.com www.agilent.com/ semiconductors For product information and a complete list of distributors, please go to our web site. For technical assistance call: Americas/Canada: +1 (800) 235-0312 or (408) 654-8675 Europe: +49 (0) 6441 92460 China: 10800 650 0017 Hong Kong: (+65) 6756 2394 India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152(Domestic/International), or 0120-61-1280(Domestic Only) Korea: (+65) 6755 1989 Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843 Data subject to change. Copyright (c) 2004 Agilent Technologies, Inc. December 23, 2004 5989-1952EN