-- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- 11 QPRO Family of XC1700D QML Configuration PROMs DS070 (v4.0) August 9, 2013 Product Specification Features Description * Certified to MIL-PRF-38535 Appendix A QML (Qualified Manufacturer Listing) * Also available under the following Standard Microcircuit Drawings (SMD): 5962-94717 and 5962-95617 The XC1700D QPROTM family of configuration PROMs provide an easy-to-use, cost-effective method for storing Xilinx FPGA configuration bitstreams. * Configuration one-time programmable (OTP) read-only memory designed to store configuration bitstreams of Xilinx FPGA devices * On-chip address counter, incremented by each rising edge on the clock input * Simple interface to the FPGA requires only one user I/O pin * Cascadable for storing longer or multiple bitstreams * Programmable reset polarity (active High or active Low) for compatibility with different FPGA solutions * Low-power CMOS EPROM process * Available in 5V version only * Programming support by leading programmer manufacturers. * Design support using the Xilinx Alliance and Foundation series software packages When the FPGA is in Master Serial mode, it generates a configuration clock that drives the PROM. A short access time after the rising clock edge, data appears on the PROM DATA output pin that is connected to the FPGA DIN pin. The FPGA generates the appropriate number of clock pulses to complete the configuration. Once configured, it disables the PROM. When the FPGA is in Slave Serial mode, the PROM and the FPGA must both be clocked by an incoming signal. Multiple devices can be concatenated by using the CEO output to drive the CE input of the following device. The clock inputs and the DATA outputs of all PROMs in this chain are interconnected. All devices are compatible and can be cascaded with other members of the family. For device programming, either the Xilinx AllianceTM or the FoundationTM series development systems compiles the FPGA design file into a standard HEX format which is then transferred to most commercial PROM programmers. X-Ref Target - Figure 1 VCC RESET/OE or OE/RESET VPP GND CEO CE CLK Address Counter EPROM Cell Matrix TC Output OE DATA DS070_01_111010 Figure 1: Simplified Block Diagram (Does Not Show Programming Circuit) (c) Copyright 1999-2013 Xilinx, Inc. XILINX, the Xilinx logo, Virtex, Spartan, ISE, and other designated brands included herein are trademarks of Xilinx in the United States and other countries. All other trademarks are the property of their respective owners. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 1 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs Pin Description DATA Data output, 3-stated when either CE or OE are inactive. During programming, the DATA pin is I/O. Note: OE can be programmed to be either active High or active Low. CLK Each rising edge on the CLK input increments the internal address counter, if both CE and OE are active. RESET/OE When High, this input holds the address counter reset and 3-states the DATA output. The polarity of this input pin is programmable as either RESET/OE or OE/RESET. To avoid confusion, this document describes the pin as RESET/OE, although the opposite polarity is possible on all devices. When RESET is active, the address counter is held at zero, and the DATA output is put in a high-impedance state. The polarity of this input is programmable. The default is active High RESET, but the preferred option is active Low RESET, because it can be driven by the FPGAs INIT pin. The polarity of this pin is controlled in the programmer interface. This input pin is easily inverted using the Xilinx HW-130 programmer software. Third-party programmers have different methods to invert this pin. CE When High, this pin disables the internal address counter, 3-states the DATA output, and forces the device into low-ICC standby mode. CEO Chip enable output, to be connected to the CE input of the next PROM in the daisy chain. This output is Low when the CE and OE inputs are both active AND the internal address counter has been incremented beyond its terminal count (TC) value. In other words: when the PROM has been read, CEO will follow CE as long as OE is active. When OE goes inactive, CEO stays High until the PROM is reset. Note: OE can be programmed to be either active High or active Low. VPP Programming voltage. No overshoot above the specified maximum voltage is permitted on this pin. For normal read operation, this pin must be connected to VCC. Failure to do so can lead to unpredictable, temperature-dependent operation and severe problems in circuit debugging. Do not leave VPP floating! VCC and GND VCC is positive supply pin and GND is ground pin. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 2 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs PROM Pinouts Table 1: PROM Pinouts Pin Name 8-pin DATA 1 CLK 2 RESET/OE (OE/RESET) 3 CE 4 GND 5 CEO 6 VPP 7 VCC 8 Capacity Table 2: Capacity Devices Configuration Bits XC1736D 36,288 XC1765D 65,536 XC17128D 131,072 XC17256D 262,144 Number of Configuration Bits, Including Header, for Xilinx FPGAs and Compatible PROMs Table 3: Number of Configuration Bits, Including Header, for Xilinx FPGAs and Compatible PROMs Device Configuration Bits PROM XC3000/A series 14,819 to 94,984 XC1765D to XC17128D XC4000 series 95,008 to 247,968 XC17128D to XC17256D XQ4005E 95,008 XC17128D XQ4010E 178,144 XC17256D XQ4013E 247,968 XC17256D Controlling PROMs Connecting the FPGA device with the PROM. * The DATA output(s) of the PROM(s) drives the DIN input of the lead FPGA device. * The Master FPGA CCLK output drives the CLK input(s) of the PROM(s). * The CEO output of a PROM drives the CE input of the next PROM in a daisy chain (if any). * The RESET/OE input of all PROMs is best driven by the INIT output of the lead FPGA device. This connection assures that the PROM address counter is reset before the start of any reconfiguration, even when a reconfiguration is initiated by a VCC glitch. Other methods--such as driving RESET/OE from LDC or system reset--assume the PROM internal power-on-reset is always in step with the FPGA's internal power-on-reset. This might not be a safe assumption. * The PROM CE input can be driven from either the LDC or DONE pins. Using LDC avoids potential contention on the DIN pin. * The CE input of the lead (or only) PROM is driven by the DONE output of the lead FPGA device, provided that DONE is not permanently grounded. Otherwise, LDC can be used to drive CE, but must then be unconditionally High during user operation. CE can also be permanently tied Low, but this keeps the DATA output active and causes an unnecessary supply current of 10 mA maximum. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 3 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs FPGA Master Serial Mode Summary The I/O and logic functions of the configurable logic block (CLB) and their associated interconnections are established by a configuration program. The program is loaded either automatically upon power up, or on command, depending on the state of the three FPGA mode pins. In Master Serial mode, the FPGA automatically loads the configuration program from an external memory. The Xilinx PROMs have been designed for compatibility with the Master Serial mode. Upon power-up or reconfiguration, an FPGA enters the Master Serial mode whenever all three of the FPGA mode-select pins are Low (M0=0, M1=0, M2=0). Data is read from the PROM sequentially on a single data line. Synchronization is provided by the rising edge of the temporary signal CCLK, which is generated during configuration. Master Serial Mode provides a simple configuration interface. Only a serial data line and two control lines are required to configure an FPGA. Data from the PROM is read sequentially, accessed via the internal address and bit counters which are incremented on every valid rising edge of CCLK. If the user-programmable, dual-function DIN pin on the FPGA is used only for configuration, it must still be held at a defined level during normal operation. Xilinx FPGAs take care of this automatically with an on-chip default pull-up resistor. Programming the FPGA With Counters Unchanged Upon Completion When multiple FPGA-configurations for a single FPGA are stored in a PROM, the OE pin should be tied Low. Upon power-up, the internal address counters are reset and configuration begins with the first program stored in memory. Since the OE pin is held Low, the address counters are left unchanged after configuration is complete. Therefore, to reprogram the FPGA with another program, the DONE line is pulled Low and configuration begins at the last value of the address counters. This method fails if a user applies RESET during the FPGA configuration process. The FPGA aborts the configuration and then restarts a new configuration, as intended, but the PROM does not reset its address counter, since it never saw a High level on its OE input. The new configuration, therefore, reads the remaining data in the PROM and interprets it as preamble, length count etc. Since the FPGA is the master, it issues the necessary number of CCLK pulses, up to 16 million (224) and DONE goes High. However, the FPGA configuration will be completely wrong, with potential contentions inside the FPGA and on its output pins. This method must, therefore, never be used when there is any chance of external reset during configuration. Cascading Configuration PROMs For multiple FPGAs configured as a daisy-chain, or for future FPGAs requiring larger configuration memories, cascaded PROMs provide additional memory. After the last bit from the first PROM is read, the next clock signal to the PROM asserts its CEO output Low and disables its DATA line. The second PROM recognizes the Low level on its CE input and enables its DATA output. See Figure 2. After configuration is complete, the address counters of all cascaded PROMs are reset if the FPGA RESET pin goes Low, assuming the PROM reset polarity option has been inverted. To reprogram the FPGA with another program, the DONE line goes Low and configuration begins where the address counters had stopped. In this case, avoid contention between DATA and the configured I/O use of DIN. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 4 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs X-Ref Target - Figure 2 VCC OPTIONAL Daisy-chained FPGAs with Different configurations DOUT OPTIONAL Slave FPGAs with Identical Configurations FPGA MODES(1) VCC 3.3V 4.7K RESET VPP DATA DATA DIN RESET VCC PROM CCLK CLK DONE CE INIT CLK CEO OE/RESET Cascaded Serial Memory CE OE/RESET (Low Resets the Address Pointer) CCLK (Output) DIN DOUT (Output) Notes: 1. For mode pin connections, refer to the appropriate FPGA data sheet. 2. The one-time-programmable PROM supports automatic loading of configuration programs. 3. Multiple devices can be cascaded to support additional FPGAs. 4. An early DONE inhibits the PROM data output one CCLK cycle before the FPGA I/Os become active. ds070_02_111010 Figure 2: Master Serial Mode DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 5 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs Standby Mode The PROM enters a low-power standby mode whenever CE is asserted High. The output remains in a high impedance state regardless of the state of the OE input. Programming The devices can be programmed on programmers supplied by Xilinx or qualified third-party vendors. The user must ensure that the appropriate programming algorithm and the latest version of the programmer software are used. The wrong choice can permanently damage the device. Table 4: Truth Table for XC1700 Control Inputs Control Inputs RESET CE Inactive Low Active Internal Address Outputs DATA CEO ICC If address < TC: increment If address > TC: don't change Active High-Z High Low Active reduced Low Held reset High-Z High Active Inactive High Not changing High-Z High Standby Active High Held reset High-Z High Standby Notes: 1. 2. The XC1700 RESET input has programmable polarity TC = Terminal Count = highest address value. TC + 1 = address 0. Note: Always tie the VPP pin to VCC in your application. Never leave VPP floating. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 6 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs XC1736D, XC1765D, XC17128D and XC17256D Absolute Maximum Ratings Table 5: Absolute Maximum Ratings Symbol Description Range Units VCC Supply voltage relative to GND -0.5 to +7.0 V VPP Supply voltage relative to GND -0.5 to +12.5 V VIN Input voltage relative to GND -0.5 to VCC + 0.5 V VTS Voltage applied to High-Z output -0.5 to VCC + 0.5 V TSTG Storage temperature (ambient) -65 to +150 C TSOL Maximum soldering temperature (10s @ 1/16 in.) +260 C Notes: 1. Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those listed under Operating Conditions is not implied. Exposure to Absolute Maximum Ratings conditions for extended periods of time may affect device reliability. Operating Conditions Table 6: Operating Conditions Symbol VCC Description Supply voltage relative to GND (TC = -55C to +125C) Military Min Max Units 4.50 5.50 V Notes: 1. During normal read operation VPP must be connected to VCC DC Characteristics Over Operating Condition Table 7: DC Characteristics Over Operating Condition Symbol Description Min Max Units VIH High-level input voltage 2.0 VCC V VIL Low-level input voltage 0 0.8 V VOH High-level output voltage (IOH = -4 mA) 3.7 - V VOL Low-level output voltage (IOL = +4 mA) - 0.4 V ICCA Supply current, active mode (at maximum frequency) - 10 mA XC17128D, XC17256D - 50 A XC1736D, XC1765D - 1.5 mA -10 10 A Input capacitance (VIN = GND, f = 1.0 MHz) sample tested - 10 pF Output capacitance (VIN = GND, f = 1.0 MHz) sample tested - 10 pF ICCS IL CIN COUT Military Supply current, standby mode Input or output leakage current DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 7 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs AC Characteristics Over Operating Condition X-Ref Target - Figure 3 CE TSCE TSCE THCE RESET/OE THOE THC TLC TCYC CLK TOE TCE TCAC TDF TOH DATA TOH DS070_03_111010 Figure 3: AC Characteristics Over Operating Condition Table 8: AC Characteristics Over Operating Condition(1)(2) Symbol XC1736D XC1765D Description XC17128D XC17256D Min Max Min Max Units TOE OE to data delay - 45 - 25 ns TCE CE to data delay - 60 - 45 ns TCAC CLK to data delay - 150 - 50 ns 0 - 0 - ns - 50 - 50 ns TOH TDF TCYC Data hold from CE, OE, or CE or OE to data float CLK(3) delay(3)(4) 200 - 80 - ns CLK Low time(3) 100 - 20 - ns THC CLK High time(3) 100 - 20 - ns TSCE CE setup time to CLK (to guarantee proper counting) 25 - 20 - ns THCE CE hold time to CLK (to guarantee proper counting) 0 - 0 - ns THOE OE hold time (guarantees counters are reset) 100 - 20 - ns TLC Clock periods Notes: 1. 2. 3. 4. AC test load = 50 pF All AC parameters are measured with VIL = 0.0V and VIH = 3.0V. Guaranteed by design, not tested. Float delays are measured with 5 pF AC loads. Transition is measured at 200 mV from steady state active levels. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 8 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs AC Characteristics Over Operating Condition When Cascading X-Ref Target - Figure 4 RESET/OE CE CLK TCDF DATA (First PROM) Last Bit First Bit TOCK TOOE TOCE TOCE CEO (First PROM) CE (Cascaded PROM) TCCE DATA (Cascaded PROM) TCCE First Bit n -1 n n Last Bit n +1 DS070_04_111010 Figure 4: AC Characteristics Over Operating Condition When Cascading Table 9: AC Characteristics Over Operating Condition When Cascading(1)(2) Symbol TCDF TOCK TOCE TOOE XC1736D XC1765D Description CLK to data float delay(3)(4) CLK to CEO CE to CEO delay(3) delay(3) RESET/OE to CEO delay(3) XC17128D XC17256D Units Min Max Min Max - 50 - 50 ns - 65 - 30 ns - 45 - 35 ns - 40 - 30 ns Notes: 1. 2. 3. 4. AC test load = 50 pF All AC parameters are measured with VIL = 0.0V and VIH = 3.0V. Guaranteed by design, not tested. Float delays are measured with 5 pF AC loads. Transition is measured at 200mV from steady state active levels. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 9 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs Ordering Information X-Ref Target - Figure 5 XC17256D DD8 M Device Number XC1736D XC1765D XC17128D XC17256D Operating Range/Processing Package Type DD8 = 8-pin Ceramic DIP M = Military (TC = -55 to +125C) B = Military (TC = -55 to +125C) QML certified to MIL-PRF-38535 ds070_05_111010 Figure 5: Ordering Information Valid Ordering Combinations Table 10: Valid Ordering Combinations XC17256DDD8M XC17128DDD8M XC1765DDD8M XC1736DDD8M 5962-9561701MPA 5962-9471701MPA Marking Information Due to the small size of the PROM package, the complete ordering part number cannot be marked on the package. The XC prefix is deleted and the package code is simplified. Devices are marked as shown in Figure 6. X-Ref Target - Figure 6 17256D DD8 M Device Number XC1736D XC1765D XC17128D XC17256D Operating Range/Processing Package Type DD8 = 8-pin Ceramic DIP M = Military (TC = -55 to +125C) B = Military (TC = -55 to +125C) QML certified to MIL-PRF-38535 ds070_06_111010 Figure 6: Marking Information Revision History The following table shows the revision history for this document: Date Version 02/08/1999 2.0 Removed the now obsolete Commercial and Industrial Grade part numbers and design support. 06/01/2000 2.1 Updated format and assigned data sheet number (DS070). 11/11/2010 3.0 Updated Notice of Disclaimer. 08/09/2013 4.0 The products in this data sheet are obsolete per XCN06002 and XCN10029. DS070 (v4.0) August 9, 2013 Product Specification Revisions www.xilinx.com 10 -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- OBSOLETE -- QPRO Family of XC1700D QML Configuration PROMs Notice of Disclaimer THE XILINX HARDWARE FPGA AND CPLD DEVICES REFERRED TO HEREIN ("PRODUCTS") ARE SUBJECT TO THE TERMS AND CONDITIONS OF THE XILINX LIMITED WARRANTY WHICH CAN BE VIEWED AT http://www.xilinx.com/warranty.htm. THIS LIMITED WARRANTY DOES NOT EXTEND TO ANY USE OF PRODUCTS IN AN APPLICATION OR ENVIRONMENT THAT IS NOT WITHIN THE SPECIFICATIONS STATED IN THE XILINX DATA SHEET. ALL SPECIFICATIONS ARE SUBJECT TO CHANGE WITHOUT NOTICE. PRODUCTS ARE NOT DESIGNED OR INTENDED TO BE FAIL-SAFE OR FOR USE IN ANY APPLICATION REQUIRING FAIL-SAFE PERFORMANCE, SUCH AS LIFE-SUPPORT OR SAFETY DEVICES OR SYSTEMS, OR ANY OTHER APPLICATION THAT INVOKES THE POTENTIAL RISKS OF DEATH, PERSONAL INJURY, OR PROPERTY OR ENVIRONMENTAL DAMAGE ("CRITICAL APPLICATIONS"). USE OF PRODUCTS IN CRITICAL APPLICATIONS IS AT THE SOLE RISK OF CUSTOMER, SUBJECT TO APPLICABLE LAWS AND REGULATIONS. CRITICAL APPLICATIONS DISCLAIMER XILINX PRODUCTS (INCLUDING HARDWARE, SOFTWARE AND/OR IP CORES) ARE NOT DESIGNED OR INTENDED TO BE FAIL-SAFE, OR FOR USE IN ANY APPLICATION REQUIRING FAIL-SAFE PERFORMANCE, SUCH AS IN LIFE-SUPPORT OR SAFETY DEVICES OR SYSTEMS, CLASS III MEDICAL DEVICES, NUCLEAR FACILITIES, APPLICATIONS RELATED TO THE DEPLOYMENT OF AIRBAGS, OR ANY OTHER APPLICATIONS THAT COULD LEAD TO DEATH, PERSONAL INJURY OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE (INDIVIDUALLY AND COLLECTIVELY, "CRITICAL APPLICATIONS"). FURTHERMORE, XILINX PRODUCTS ARE NOT DESIGNED OR INTENDED FOR USE IN ANY APPLICATIONS THAT AFFECT CONTROL OF A VEHICLE OR AIRCRAFT, UNLESS THERE IS A FAIL-SAFE OR REDUNDANCY FEATURE (WHICH DOES NOT INCLUDE USE OF SOFTWARE IN THE XILINX DEVICE TO IMPLEMENT THE REDUNDANCY) AND A WARNING SIGNAL UPON FAILURE TO THE OPERATOR. CUSTOMER AGREES, PRIOR TO USING OR DISTRIBUTING ANY SYSTEMS THAT INCORPORATE XILINX PRODUCTS, TO THOROUGHLY TEST THE SAME FOR SAFETY PURPOSES. TO THE MAXIMUM EXTENT PERMITTED BY APPLICABLE LAW, CUSTOMER ASSUMES THE SOLE RISK AND LIABILITY OF ANY USE OF XILINX PRODUCTS IN CRITICAL APPLICATIONS. DS070 (v4.0) August 9, 2013 Product Specification www.xilinx.com 11