I -i7 MEMS Rate Sensors for Space Joel Gambino NASA/GSFC, Guidance, Navigation and Control Center Greenbelt, Md Currently, MEMS Rate Sensor ABSTRACT systems are being produced for terrestrial and missile Micromachined Electro Mechanical applications. Therefore they System (MEMS) Rate Sensors offer have relatively coarse many advantages that make them performance, a large rate range attractive for space use. They (up to i000 deg/sec), and are are smaller, consume less power, not radiation hardened. Before and cost less than the systems this technology can be used for currently available. MEMS Rate attitude control on spacecraft, Sensors however, have not been design issues must be addressed. optimized for use on spacecraft. This paper describes an approach To address these design issues, to developing MEMS Rate Sensors a program has been initiated at systems for space use. the GSFC that seeks to optimize the MEMS Rate Sensor for space INTRODUCTION use and develop a MEMS based Inertial Reference Unit (IRU) Spacecraft designers are for space use. This paper will striving to replace traditional summarize the results to date of heavy, power-hungry mechanical the optimization effort and gyro systems with lightweight describe two approaches for and extremely reliable solid development of an IRU. state rate sensing systems. One such system is the micromachined MEMS GYROS gyroscope. These systems offer extremely small size (about 8 Advances in micromachining have in^3), low weight (less than 3 enabled the fabrication of very ibs.), low power (3 watts), and small, low cost inertial much lower cost then the sensors. These MEMS "Gyros" existing technology gyros used sense angular rates by measuring in space applications. coriolis forces acting on a vibrating mass. This vibrating Many satellites of the future mass or sensing element is will be much smaller than those typically etched in silicon or currently being produced. quartz which is driven Hundreds of "nano-satellites" electrostatically into launched and released into oscillation. When a rate is various orbits for space and applied to the sensor, the earth science missions have been deflection of the sensing proposed. The mass and power element due to coriolis forces budgets for these satellites is capacitively sensed. This will be less than what a single deflection signal is ACS component now consumes. The proportional to the angular potential for small size and low input rate of the sensor. cost of the MEMS rate sensor make it an attractive option for these future satellites. SYSTEMS AVAILABLE TODAY: encouraging organizations who show interest in this area. Two There are several microgyro manufacturers that have shown based IRU systems available interest in developing space commercially. They combine microgyros are Draper Laboratory microgyros, accelerometers, and and Kear fott Corp. Both have some even include GPS navigation extensive experience in to provide position information. designing, building, and testing The size of these systems is on qyro systems for space and both the order of 25 to 40 in^3. are working with NASA/GSFC to Their power consumption is less produce microgyro systems for than i0 watts. space. Draper is studying ways to optimize sensors for space Several off the shelf units were while Kearfott is constructing a obtained for testing and single axis sensor package with evaluation at the GSFC. One of a dynamic range and bandwidth the units obtained was the scaled for space use. Systron Donner Motion Pak IMU. This unit combines three quartz TOP VIEW ! vl_r_u tuning fork gyros with three quartz accelerometers. Also LEFT SENSE _ RIGHT _N_£ obtained was a Boeing Digital Quartz IMU (DQI) [I]. This unit uses quartz gyros built by Systron Donner that have better performance than those used in the Motion Pak IMU. STRUCTURE _ _ SUPPORT ANCHOR POINT The most recent acquisition was OUT_T that of the Boeing Beta Rate VIBRATING MASSES Sensor. It uses a silicon SIDE VIEW micromachined gyro developed by Draper Laboratory [2][3]. These LEFT RIGHT gyros which are packaged DRIVE DRIYE individually, promise good MO_'R_MU'I_'R performance and flexibility. Also, Draper continues to 5£NS£ PLA TZ REBApLLAANTCEE downsize and improve the Draper Microgyro performance of these units which will be used to produce a micro Inertial Measurement Unit (IMU). MICROGYRO OPTIMIZATION FOR SPACE The performance of microgyros is Most of the Microqyro systems very coarse when compared to currently being produced are systems currently used for space designed for automobiles and applications. The market is ballistic missiles. They have driven by military and very high dynamic ranges (up to automotive customers where ultra i000 deg/sec) and high low noise performance is not of bandwidths (greater than 50 Hz). prime concern. This low market Spacecraft on the other hand, demand and high performance typically require a relatively requirement explains why few low dynamic range (5 to I0 microgyro manufacturers have deg/sec) and can live with lower sought to provide space units. bandwidths (less than i0 Hz). Also, the performance of As a result, the GSFC has sought currently available units makes to develop space microgyros by them useable in very limited further increase performance as applications. well as making the unit radiation tolerant. The Microgyro effort at GSFC seeks to improve the performance of Microgyro systems to a level that would be useful for _,,- _00 Hz MAX spacecraft missions by optimizing both the gyro sensing element and the electronics. To this end, we have teamed with __ y Kearfott to develop space specific gyro sensors. Also, b OUTPUT _> RODTITAHTEIORN ROTAT_N FREQUENCY the GSFC is also exploring ways f* to improve the performance of "off the shelf" units. Current $UBSTRATE ACCELEP_kTION az efforts involve rescaling the %-m;, _'c m(_x J_) dynamic range of existing sensors, optimizing the Kearfott Microgyro ] electronics for low noise, and filtering sensor output. GSFC DEVELOPMENT 4A (i) The GSFC is also working to develop an IRU from commercially o o available sensors. Two approaches for IRU development are presented. First, a 3 axis Bandwidth IRU packaged as a single unit is (deg/hr) > 5Hz > 5Hz being assembled from 3 individual Microgyro modules. Angle Random Second, one or more microgyro Walk (deg/rt-Hz) 1 0.01 modules will be integrated onto an industry standard (compact Bias (deg/hr) 40 0.I PCI) board to produce a building block for a modular Attitude Power (watts) 3 0.5 Control system (ACS). Kearfott is producing an MODULAR ACS IRU CARD: engineering model microgyro scaled to +/- i0 degree/second With requirements for systems to dynamic range. It is hoped that be smaller, cheaper, and lower lowering the dynamic range will power, spacecraft designers are improve the noise challenged to come up with characteristics of the unit. innovative approaches to spacecraft systems. One such In the NASA/GSFC lab, we are approach is the Modular ACS. experimenting with filtering the The idea is to construct ACS gyro output to improve noise building blocks using a standard performance. interface. Each board will provide one or more ACS In the future, redesign of the functions. This approach will sensing element will be minimize the amount of redesign investigated as well as reducing necessary for new spacecraft. bandwidth in an effort to MICRO IRU: Future work will be done to characterize the effects of A micro Inertial Reference Unit reducing dynamic range and (IRU) will be fabricated from 3 bandwidth. Development will single microgyro modules, a continue as advances are made in power supply, and interface sensor design. electronics. The overall size of the IRU will be 27 in^3. The unit will weigh about 1 lb. and consume about 3 watts. The first prototype IMU will be constructed using gyro modules built by Boeing. These units operate from a single +5 volt supply and provide a voltage output which is linear over the REFERENCES input rate dynamic range. Preliminary testing indicates [i] R. P. Jaffe "DQI Technical the need for filtering of this Description and Performance output to reduce high frequency noise. Capability", AIAA 96-3711, July 29-31 1996. CONCLUSIONS [2] J. Bernstein, S. Cho, A. T. King, A. Kourepenis, P. Maciel, Due to low demand and high and M. Weinberg, "A performance requirements, few vendors are interested in Micromachined Comb-Drive Tuning Fork Rate Gyroscope", IEEE 0- developing microgyro systems for 7803-0957-2/93. space applications. [3] N. Barbour , J. Connelly, J. The performance of currently Gilmore, P. Greiff, A. available microgyro systems is Kourepenis, M. Weinberg, adequate for only a small number "Micromechanical Silicon of space applications but the Instrument and Systems advantages offered by this Development at Draper technology justify further Laboratory", AIAA 96-3709, July development. 29-31, 1996.