Architecture of a Programmable Pattern Generator (PATGEN) ASIC for Space Applications

1. Architecture of a Programmable Pattern Generator (PATGEN)ASIC for Space Applications W. C. Wilson1, R. F. Hodson2, and C. D. Armstrong1 1NASA Langley Research Center 2Christopher Newport University

2. Introduction to PATGEN • The Pattern Generator (PATGEN) avionics project is developing a custom Application Specific Integrated Circuit (ASIC) for detector clocking. • The PATGEN ASIC is a Focal Plane Array (FPA) or Charge Coupled Device (CCD) clock and control signal generation device for space applications. • PATGEN will have 8 outputs, but is is extendable in both the number of output channels and the size of the patterns. • The chip is a digital pattern generation chip with two levels of looping. • Patterns can be either single shot or continuous. • PATGEN is implemented in Silicon On Insulator (SOI) technology for radiation tolerance. W. C. Wilson E6A

3. Graphical Entry tool Configuration Memory PROM • Custom ASIC Design • Radiation Hard • 100K rads TID • Latchup Immune • 8 Channels • Up to 256 Gbit Pattern length. • 2 Levels of 16K looping. • PATGEN is extendible • The number of output channels. • The size of the patterns. PATGEN CCD or FPA Or Any digital logic Clock or Control Signals CCD Array W. C. Wilson E6A

4. Project Partners NASA Langley Research Center Christopher Newport University LaRC CNU W. C. Wilson E6A

5. Extendibility of PATGEN CCD or FPA Analog Signals • 2D Array of PATGEN Chips • Increase the number of Channels • Increase the Pattern Length • Arrays boot from a single PROM Clocking and Control Signals PATGEN PATGEN Increase the Pattern Length PROM PATGEN PATGEN Configuration Data Increase the number of Channels W. C. Wilson E6A

6. Technology Peregrine Semiconductor 0.5u UTSi CMOS Transistors P-channel FET N-channel FET Silicon Dioxide Insulating Sapphire Substrate • Radiation Hardened: • Single event upsets (SEU) less than 10-8 errors/bit-day • Single Event Latchup (SEL) immunity • Total dose hardness to 100 Krads • Low power (30% lower than Bulk CMOS) • Higher performance (due to less parasitics) • Low Cost (Available through MOSIS in small quantities) W. C. Wilson E6A

7. Continuous or Single Fire < 16K Iterations < 16K Iterations < 16K < 16K < 16K < 16K < 16K < 16K < 16K < 16K Fn Fn Fn Fn Fn Fn Fn Fn < 64 bits < 64 bits < 64 bits < 64 bits < 64 bits < 64 bits < 64 bits < 64 bits < 4 fields < 4 fields < 4 Groups PATGEN Looping Structure W. C. Wilson E6A

8. PATGEN Looping Structure • The PATGEN device has eight channels with eight fields per channel. • The device also implements two levels of looping. • The lowest level of looping is implemented as 16K iterations on each of eight 64-bit fields. • The sequencer has four groups in which each group is made up of a sequence of up to four fields. • The second level of looping is 16K iterations on each group sequence. W. C. Wilson E6A

9. PATGEN Top Level Chip Controller Bit Error Parity . Channel 1 Channel 8 . Channel 2 Channel 7 . Channel 3 Channel 6 . Channel 4 Channel 5 W. C. Wilson E6A

10. PATGEN Top Level • The PATGEN chip consists of the following: • Chip controller. • State Machine to control the modes of operation. • Eight identical Channels. • Each channel is made of 8 fields of 64 bits each. • The Parity block. • Used for Parity and Built In Self Test (BIST) • Bit Error block. • Used for SEU detection. W. C. Wilson E6A

11. PATGEN Channel block diagram Field Length Control Field Mux Select Lines Field #1 Field Enables Field #2 Field Select Field #3 Pattern Output Sequencer Mux & OE Field #4 . Field #5 Field #6 Channel Controller Field #7 Field #8 W. C. Wilson E6A

12. PATGEN Channel block diagram • The PATGEN channel block is comprised of: • The channel controller block. • State Machine, controls modes of operations. • The multiplexor and output enable block. • Provides Tri-state (High Impedance) and output selection. • The field length control block. • Allows each field to vary in length from 1 to 64 bits. • Eight identical field blocks. • 64 bit variable length cyclic shift registers. • The sequencer block. • Sequences the fields to make up patterns. W. C. Wilson E6A

13. PATGEN Variable Length Cyclic Shift Register SS DFF DFF DFF DFF Feedbk Feedbk Feedbk Feedbk B B B B D DataIn D D Data Out D SS Q A Q Q A Q A A Sel Sel Sel Sel QB QB QB QB MuxSel 62 MuxSel 63 MuxSel 1 MuxSel 0 CLK SS W. C. Wilson E6A

14. PATGEN Variable Length Cyclic Shift Register • The shift register is built of flip-flops and multiplexors. • Multiplexors allow for variable length from 1 to 64 bits. • Shift register allows for looping. • Patterns shifted out are also shifted back in. • Eliminates need for separate data storage for the patterns. W. C. Wilson E6A

15. Q D QB Mux & OE Block Diagram F1 F2 F3 Mux 4:1 F4 Channel Out Mux 2:1 F5 F6 Mux 4:1 F7 F8 2 FSel 3 1 OE Mask Register CLK W. C. Wilson E6A

16. Mux & OE Block Diagram • Mux&OE block controls and selects the output from the eight fields that make up a channel. • The PATGEN has two output modes, binary and tertiary mode. • In Binary mode, outputs are either high or low. • The mask bit is cleared. • The multiplexor uses outputs from the sequencer block to select from one of the eight fields to be output. • In Tertiary mode, outputs can be high, low or tri-state (high impedance state). • The mask bit is set • The four upper fields are used to set the pattern output to a high or low. • The four lower fields are used as masks, for when the pattern should be tri-stated. W. C. Wilson E6A

17. Length Count Length Count Length Count Length Count Seq. Count Seq. Count Seq. Count Seq. Count 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register 4 bit Cyclic Shift Register Sequencer Block diagram Group Counter 3 3 Mux 4(3:1) 3 3 3 W. C. Wilson E6A

18. Sequencer Block diagram • The sequencer block, is comprised of four groups of sequencers. • The groups are made up of small sequencers that each sequence up to four fields. • Each group has its own loop counter which allows up to 16K iterations. • Each group is made up of a set of three four-bit cyclic shift registers. • The output of the shift registers selects and enables the active fields, and it drives the select lines of the output multiplexor. • The group counter controls the number of groups up to four, which can be chained together. • Allows up to 16 fields (four groups of four fields) to be sequenced. W. C. Wilson E6A

19. Conclusions/Status • The PATGEN chip is a pattern generation ASIC. • PATGEN can be placed in arrays to extend the number of outputs and length of the patterns. • Within the chip, there are two levels of looping, each with 16K iterations. • The patterns are made up of eight 64-bit fields. • Patterns can be continuous or single shot. • Pattern lengths vary up to 256 Gbits, depending the amount of looping. • The PATGEN programming software, a graphical entry tool for developing patterns, has been written, tested and documented. • The project has fabricated a prototype PATGEN device • Fabricated using Peregrine’s 0.5u SOS process through MOSIS. • The prototype has two channels and the fields are 32 bits wide. • Device testing will begin in October of 2000. W. C. Wilson E6A