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? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? 1 ? ? ? ? ? ? device highlights flexible programmable logic ? 0.25 , 5 layer metal cmos process ? 2.5 v vcc, 2.5/3.3 v dive capable i/o ? up to 4032 logic cells ? up to 583,000 max system gates ? up to 347 i/o embedded dual port sram ? up to thirty-six 2,304-bit dual port sram blocks ? up to 82,900 ram bits ? ram/rom/fifo wizard for automatic configuration ? configurable and cascadable applications ? signal processing operators ? signal processing functions ? networking/communications for voip ? speech/voice processing ? channel coding programmable i/o ? high performance: <3.2 ns tco ? programmable slew rate control ? programmable i/o standards: lvttl, lvcmos, pci, gtl+, sstl2, and sstl3 eight independent i/o banks three register configurations: input, output and output enable advanced clock network ? nine global clock networks one dedicated eight programmable ? sixteen i/o (high-drive) networks ? twenty quad-net networks: five per quadrant figure 1: eclipse block diagram embedded ram blocks pll pll fabric embedded ram blocks pll pll combining performance, density, and embedded ram eclipse family data sheet
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 2 quickworks design software the quickworks ? package provides the most complete esp an d fpga software solution from design entry to logic synthesis, to place and route to simulation. the packages provide a solution for designers who use third party tools from cadence, mentor, orcad, synopsys, viewlogic and other third-party tools for design entry, synthesis, or simulation. process data eclipse is fabricated on a 0.25 m five-layer metal cmos process. the core voltage is 2.5 v v cc supply and 3.3 v tolerant i/o with the addition of 3.3 v v ccio . eclipse is available in commerc ial, industrial, and military temperature grades. programmable logic architectural overview the eclipse logic cell structure is presented in figure 2 . this architectural feature addresses current register- intensive designs. table 1: eclipse product family members ql6250 ql6325 ql6500 ql6600 max gates 248,160 320,640 488,064 583,008 logic array 40x24 48x32 64x48 72x56 logic cells 960 1,536 3,072 4,032 max flip-flops 2,670 4,002 7,185 9,105 max i/o 250 310 347 347 ram modules 20 24 32 36 ram bits 46,100 55,300 73,700 82,900 packages pqfp 208 208 - - pbga (1.27 mm) - - 516 516 fpbga (1.0 mm) 484 484 484 484 lfbga (0.8 mm) 280 280 280 280 table 2: max i/o per device /package combination device 208 pqfp 280 fpbga 484 pbga 516 pbga ql6250 99 163 250 - ql6325 99 163 310 - ql6500 - 163 327 347 ql6600 - 163 327 347
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 3 figure 2: eclipse logic cell the second register has a two-to-one multiplexer controll ing its input. the register can be loaded from the nz output or directly from a dedicated input. note: the input ?pp? is not an ?input? in the classical sens e. it can only be tied high or low using default links only and is used to select which path ?nz? or ?ps? is used as an input to the register. all other inputs can be connected not only to ?tiehi? and ?tielo? but to multiple routing channels as well. the complete logic cell consists of 2 six-input and ga tes, 4 two-input and gates, 7 two-to-one multiplexers, and 2 d flip-flop with asynchronous set and reset controls. the cell has a fan-in of 30 (including register control lines) and fits a wide range of functions wi th up to 17 simultaneous inputs. it has 6 outputs; 4 combinatorial and 2 registered. the high logic capacity and fan-in of the logic cell accommodate many user functions with a single level of lo gic delay while other architectures re quire two or more levels of delay. table 3: performance standards function description slowest speed grade fastest speed grade multiplexer 16:1 5 ns 2.8 ns parity tree 24 6 ns 3.4 ns 36 6 ns 3.4 ns counter 16 bit 250 mhz 450 mhz 32 bit 250 mhz 450 mhz fifo 128 x 32 155 mhz 280 mhz 256 x 16 155 mhz 280 mhz 128 x 64 155 mhz 280 mhz clock to out 4.5 ns 2.5 ns system clock 200 mhz 400 mhz qs a1 a2 a3 a4 a5 a6 os op b1 b2 c1 c2 ms d1 e1 n p e2 d2 n s f1 f3 f5 f6 f2 f4 ps pp mp az oz qz n z fz q2z qc qr
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 4 ram modules the eclipse family includes multip le dual-port 2,304-bit ram modules for implementing ram, rom and fifo functions. each module is user-c onfigurable into four different block organizations. modules can also be cascaded horizontally to incr ease their effective width or vertically to increase their effective depth as shown in figure 3 . the ram can also be configured as a modified harvard architecture, similar to those found in dsps. figure 3: 2,304-bit eclipse ram module the number of ram modules varies fr om 20 to 36 blocks within the eclipse family, for a total of 46.1 to 82.9 k bits of ram. using two ?mode? pins, designers can configure each module into 128 x 18 (mode 0), 256 x 9 (mode 1), 512 x 4 (mode 2), or 1024 x 2 blocks (mode 3) . the blocks are also easily cascadable to increase their effective width and/or depth. see figure 4 . figure 4: cascaded ram modules the ram modules are dual-port, with completely independent read and write ports and separate read and write clocks. the read ports support asynchro nous and synchronous operation, while the write ports support synchronous operation. each port has 18 data lines and 10 address lines, allowing word lengths of up to 18 bits and address spaces of up to 1024 wo rds. depending on the mode selected, however, some higher order data or address lines may not be used. mode[1:0] wa[9:0] wd[17:0] we wclk a syncrd ra[9:0] rd[17:0] re rclk wdata rdata rdata waddr wdata raddr ram module (2,304 bits) ram module (2,304 bits)
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 5 the write enable (we) line acts as a clock enable for synchronous write operation. the read enable (re) acts as a clock enable for synchronous read operation (a syncrd input low), or as a flow-through enable for asynchronous read operation (asyncrd input high). designers can cascade multiple ram modules to increase the depth or width allowed in single modules by connecting corresponding address lines together and dividing the words between modules. a similar technique can be used to cr eate depths greater than 512 words. in this case address signals higher than the ninth bit are encoded onto the write enable (w e) input for write operations. the read data outputs are multiplexed together using encoded higher re ad address bits for the multiplexer select signals. the ram blocks can be loaded with da ta generated internally (typically for ram or fifo functions) or with data from an external prom (typically for rom functions). phase locked loops (plls) instead of requiring extra components, designers simply need to instantiate one of the pre-configured models described in this section and listed in table 4 . the quicklogic built-in plls support a wider range of frequencies than many other plls. also, quicklogic p lls can be cascaded to su pport different ranges of frequency multiplications or divisions, driving the device at a faster or slower rate than the incoming clock frequency. most importantly, they achieve a very shor t clock-to-out time?generally less than 3 ns. this low clock-to-out time is achieved by th e pll subtracting the clock tree delay through the feedback path, effectively making the clock tree delay zero. figure 5 illustrates a typical quicklogic esp pll. figure 5: pll block vco filter fin fout + - 1st quadrant 2nd quadrant 3rd quadrant 4th quadrant clock tree frequency divide frequency multiply 1 . _ . 2 . _ . 4 . _ . 4 . _ . 2 . _ . 1 . . _ pll bypass
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 6 f in represents a very stable high-frequency input clock and produces an accurate signal reference. this signal can either bypass the pll entirely, thus entering the cl ock tree directly, or it can pass through the pll itself. within the pll, a voltage-controlled oscillator (vco) is added to the circuit. the external f in signal and the local vco form a control loop. the vco is multiplied or divided down to the reference frequency, so that a phase detector (the crossed circle in figure 5 ) can compare the two signals. if the phases of the external and local signals are not within the tolerance required, the phase detector sends a signal through the charge pump and loop filter ( figure 5 ). the charge pump generates an error voltage to bring the vco back into alignment and the loop filter removes any high frequency noise before the error voltage enters the vco. this new vco signal enters the clock tree to drive the chip's circuitry. f out represents the clock signal that emerges from the outp ut pad (the output signal pllpad_out is explained in table 5 ). this clock signal is meaningful only when the p ll is configured for external use; otherwise, it remains in high z state, as shown in the post-simulation waveform. most quicklogic products contain four plls, one to be used in each quadrant. the pll presented in figure 5 controls the clock tree in the fourth quadrant of its esp. as previously mentioned, quicklogic plls compensate for the additional delay created by the clock tree itself by subtracting the clock tree delay through the feedback path. for more specific information on the phase loc ked loops, refer to application note 58 at http://www.quicklogic.com /images/appnote58.pdf . pll modes of operation quicklogic plls have eight modes of operation, base d on the input frequency and desired output frequency? table 4 indicates the features of each mode. table 4: pll mode frequencies pll model output frequency input frequency range a a. the input frequency can range from 12.5 mhz to 500 mhz, whil e output frequency ranges from 25 mhz to 250 mhz. when you add plls to your top-level design, be sure that the pll mode matches your desired input and output frequencies. output frequency range pll_hf b b. hf stands for high frequency and lf stands for low frequency. same as input frequency 66 mhz?150 mhz 66 mhz?150 mhz pll_lf same as input frequency 25 mhz?133 mhz 25 mhz?133 mhz pll_mult2hf 2 input frequency 50 mhz?125 mhz 100 mhz?250 mhz pll_mult2lf 2 input frequency 16 mhz?50 mhz 32 mhz?100 mhz pll_div2hf 1/2 input frequency 100 mhz?250 mhz 50 mhz?125 mhz pll_div2lf 1/2 input frequency 50 mhz?100 mhz 25 mhz?50 mhz pll_mult4 4 input frequency 16 mhz?40 mhz 64 mhz?160 mhz pll_div4 1/4 input frequency 100 mhz?300 mhz 25 mhz?75 mhz
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 7 pll signals table 5 summarizes the key signals in quicklogic plls. note: for pll ac specifications, contact the factory. table 5: pll signals signal name description pllclk_in a a. because pllclk_in and pllrst signals have inpad, and pll pad_out has outpad, you do not have to add additional pads to your design. input clock signal pllrst active high reset if pllrst is asserted, then clknet_o ut and pllpad_out are reset to 0. this signal must be asserted and then released in order for the lock_detect to work. onn_offchip pll output this signal selects whether the pll will drive the internal clock network or be used off- chip. this is a static signal, not a dynamic signal. tied to gnd = outgoing signal drives internal gates. tied to vcc = outgoing signal used off-chip. clknet_out out to internal gates this signal bypasses the pll logic before driving the internal gates. note that this signal cannot be used in the same quadrant where the pll signal is used (pllclk_out). pllclk_out out from pll to internal gates this signal can drive the internal gates after going through the pll. for this to work, onn_offchip must be tied to gnd. pllpad_out out to off-chip this outgoing signal is used off-chip. for this to work, onn_offchip signal must be tied to vcc. lock_detect active high lock detection signal note: for simulation purposes, this signal gets asserted after 10 clock cycles. however, it can take a maximum of 200 clock cycles to sync with the input clock upon release of the reset signal.
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 8 i/o cell structure eclipse features a variety of distinct i/o pins to maximize performance, functionality, and flexibility with bi- directional i/o pins and input-only pins. all i/o pins are 2.5 v and 3.3 v tolerant and comply with the specific i/o standard selected. all dedicated input pins are 2.5 v tolerant and comply with the lvcmos2 standard.for single ended i/o standards, v ccio specifies the input tolera nce and the output drive. for voltage referenced i/o standards (e.g., sstl), the voltage supplied to the inref pins in each bank specifies the input switch point. for example, the v ccio pins must be tied to a 3.3 v supply to provide 3.3 v compliance. eclipse can also support the lvds and lvpecl i/o standard s with the use of external resistors (see table 6 ). as designs become more complex and requirements more stringent, several application-specific i/o standards have emerged for specific applications. i/o standa rds for processors, memori es, and a variety of bus applications have become commonplace and a requirem ent for many systems. in addition, i/o timing has become a greater issue with specific requirements for setup, hold, clock to out, an d switching times. eclipse has addressed these new system requirements and now in cludes a completely new i/o cell which consists of programmable i/os as well as a new cell structure c onsisting of three register s?input, output, and output enable (oe). eclipse offers banks of prog rammable i/os that address many of the bus standards that are popular today. as shown in figure 6 each bi-directional i/o pin is associated with an i/o cell which features an input register, an input buffer, an output register, a three-state output buffer, an output enable register, and 2 two-to-one output multiplexers. table 6: i/o standards and applications i/o standard inref reference voltage output voltage application lvttl n/a 3.3 general purpose lv c m o s 2 n/a 2.5 general purpose pci n/a 3.3 pci bus applications gtl+ 1.0 n/a backplane sstl3 1.5 3.3 sdram sstl2 1.25 2.5 sdram
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 9 figure 6: eclipse i/o cell the bi-directional i/o pin options can be programmed for input, output, or bi-directional operation. as shown in figure 6 , each bi-directional i/o pin is associated with an i/o cell which features an input register, an input buffer, an output register, a three-state output buffer, an output enable register, and 2 two-to-one multiplexers. the select lines of the two-to-one multiplexers are static and must be connected to either v cc or gnd. for input functions, i/o pins can prov ide combinatorial, registered data, or both options simultaneously to the logic array. for combinatorial input operation, data is routed from i/o pins through the input buffer to the array logic. for registered input operation, i/o pins driv e the d input of input cell re gisters, allowing data to be captured with fast se t-up times without consuming internal logi c cell resources. the comparator and multiplexor in the input path allows for native support of i/o standards with reference points offset from traditional ground. for output functions, i/o pins can receive combinatorial or registered data from the logic array. for combinatorial output operation, data is routed from th e logic array through a multiplexer to the i/o pin. for registered output operation, the array logic drives the d input of the output cell regi ster which in turn drives the i/o pin through a multiplexer. the multiplexer allows either a combinatorial or a registered signal to be driven to the i/o pin. the addition of an output register will also decrease the tco. since the output register does not need to drive the ro uting the length of the outp ut path is also reduced. the three-state output buffer controls the flow of data from the array logic to the i/o pin and allows the i/o pin to act as an input and/or output. the buffer's output enable can be indi vidually controlled by the logic cell array or any pin (through the regular routing resources), or it can be bank-controlled through one of the global networks. the signal can also be either combinatorial or re gistered. this is identical to that of the flow for the output cell. for combinatorial control operation data is routed from the logic array through a multiplexer to the three-state control. the ioctrl pins can directly dr ive the oe and clk signals fo r all i/o cells within the same bank. e r q d r q e r q d + - pad output enable register output register input register d
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 10 for registered control operation, the array logic drives th e d input of the oe cell register which in turn drives the three-state control through a multiplexer. the multip lexer allows either a combinatorial or a registered signal to be driven to the three-state control. when i/o pins are unused, the oe cont rols can be permanently disabled, allowing the output cell register to be used for registered feedback into the logic array. i/o cell registers are controlled by clock, clock enable , and reset signals, which can come from the regular routing resources, from one of the global networks, or from two ioctrl input pins per bank of i/os. the clk and reset signals share common lines, while the cl ock enables for each regist er can be independently controlled. i/o interface support is programmable on a per bank basis. figure 7 illustrates the i/o bank configurations. each i/o bank is independent of other i/ o banks and each i/o bank has its own v ccio and inref supply inputs. a mixture of different i/o standards can be used on the device; however, there is a limitation as to which i/o standards can be supported within a gi ven bank. only standards that share a common v ccio and inref can be shared within the same bank (e.g., pci and lvttl). figure 7: multiple i/o banks embedded ram blocks pll pll fabric embedded ram blocks pll pll vccio 0 inref 0 vccio 1 inref 1 vccio 2 inref 2 vccio 3 inref 3 inref 4 vccio 4 inref 5 vccio 5 inref 6 vccio 6 inref 7 vccio 7
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 11 programmable slew rate each i/o has programmable slew rate capability. the ra te is programmable to one of two slew rates either fast or slow. the slower rate can be used to reduce ground bounce noise. programmable weak pull-down programmable weak-pull down resistor is available on each i/o. the i/o weak pull-down eliminates the need for external pull down resistor for used i/o. the sp ec for pull-down current is maximum of 150 a under worst case condition. figure 8: programmable i/o weak pull-down i/o output logic pa d
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 12 clock networks global clocks there are eight global clock networks in the eclipse devi ce family. global clocks can drive logic cell, i/o, and ram blocks in the device. five global clocks have acce ss to a quad net (local clock network) connection with a programmable connection to the register inputs. gl obal clock pins are 2.5 v, lvcmos2, compliant. figure 9: global clock methodology quad net clk pin global clock net
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 13 quad-net network there are five quad-net local clock networks in each qu adrant for a total of 20 in a device. each quad-net is local to a quadrant. before driving th e columns clock buffers, the quad-net is driven by the output of a mux which selects between the clk input and an internally generated clock source (see figure 10 ). figure 10: global clock structure schematic dedicated clock there is one dedica ted clock each device of the eclipse fa mily (ql6250, ql6325, ql6500, and ql6600). this clock connects to the clock inpu t of the logic cell and i/o registers, and ram blocks th rough a hardwired connection and is multiplexed with th e programmable clock input. the dedica ted clock provides a fast global network with low skew. users have the ability to select either the dedicated clock or the programmable clock ( figure 11 ). the dedicated clock is 2.5 v, lvcmos2, compliant. figure 11: dedicated clock circuitry within logic cell note: for more information on the clocking capabilitie s of eclipse fpgas, re fer to the quicklogic application note 68 at http://www.quicklogic.com/images/appnote68.pdf . i/o control and local hi-drives each bank of i/os has two input-only pins that can be programmed to drive the rst, clk and en inputs of i/os in that bank. these input only pins also serve as high drive inputs to a quadrant. as an i/o control or high drive, these buffers can be driven by the internal logic. i/o control pins, called ioctrl in the pin tables, are 2.5 v, lvcmos2, compliant. t pgck t bgck internally generated clock, or clock from general routing network global clock (clk) input global clock network ff global clock buffer programmable clock or general routing dedicated clock clk
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 14 programmable logic routing eclipse devices are delivered with six types of routing resources as follows: short (sometimes called segmented) wires, dual wires, quad wires, express wires, distri buted networks, and default wires. short wires span the length of one logic cell, always in the vertical direction. dual wires run horizontally and span the length of two logic cells. short and dual wires are predominantly used for local connections. default wires supply v cc and gnd (logic ?1? and logic ?0?) to each column of logic cells. quad wires have passive link interconne ct elements every fourth logic cell. as a result, these wires are typically used to implement intermediate length or medium fan-out nets. express lines run the length of the programmable logi c uninterrupted. each of these lines has a higher capacitance than a quad, dual, or short wire, but less capacitance than shorter wires connected to run the length of the device. the resistance is lower because th e express wires do not require the use of ?pass? links. express wires provide higher performance for long routes or high fan-out nets. distributed networks are described in the clock/contro l section. these wires span the programmable logic and are driven by ?column clock? buffers. all clock network pin buffers (dedicated and gl obal) are hard wired to individual sets of column clock buffers. global por (power-on reset) the eclipse family of devices features a global power-on reset. this reset is hardwired to all registers and resets them to logic ?0? upon power-up of the device. in quic klogic devices, the asynchro nous reset input to flip- flops has priority over the set input. therefore, the gl obal por resets all flip-flop s during power-up. if you want to set the flip-flops to logic ?1?, you must assert the ?set? signal after the global por signal has been deasserted. figure 12: power-on reset vcc power-on reset q xxxxxxx 0
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 15 joint test access group (jtag) figure 13: jtag block diagram microprocessors and application specific integrated circuits (asics) pose many design challenges, not in the least of which concerns the accessibilit y of test points. the joint test acce ss group (jtag) formed in response to this challenge, resulting in ieee standard 1149.1, the standard test access port and boundary scan architecture. the jtag boundary scan test methodology allows complete observation and control of the boundary pins of a jtag-compatible device through jtag software. a test access port (tap) controller works in concert with the instruction register (ir), which allow users to run th ree required tests along with several user-defined tests. jtag tests allow users to reduce syst em debug time, reuse test platforms and tools, and reuse subsystem tests for fuller verification of higher level system elements. the 1149.1 standard requires the following three tests: ? extest instruction. the extest instruction performs a pcb interc onnect test. this test places a device into an external boundary test mode, selecting the bounda ry scan register to be connected between the tap's test data in (tdi) and test data out (tdo) pins. boun dary scan cells are preloade d with test patterns (via the sample/preload instruction), and input boundary cells captur e the input data for analysis. ? sample/preload instruction. this instru ction allows a device to remain in its functional mode, while selecting the boundary scan register to be connect ed between the tdi and tdo pins. for this test, the boundary scan register can be accessed via a data scan operation, allowing users to sample the functional data entering and leaving the device. tck tms trstb rdi tdo instruction decode & control logic tap controller state machine (16 states) instruction register boundary-scan register (data register) mux bypass register mux internal register i/o registers user defined data register
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 16 ? bypass instruction. the bypass instruction allows data to skip a device's boundary scan entirely, so the data passes through the bypa ss register. the bypass instruction allows users to test a device without passing through other devices. the bypass register is connected between the tdi and tdo pins, allowing serial data to be transferred through a device withou t affecting the operation of the device. jtag bsdl support ? bsdl-boundary scan description language ? machine-readable data for test equipment to generate testing vectors and software ? bsdl files available for all device/p ackage combinations from quicklogic ? extensive industry support available and automatic test-vector generation (atg) security fuses there are two security links: one to disable reading logic from the array, and the second to disable jtag access to the device. programming these opti onal links completely disables acce ss to the device from the outside world and provides an extra level of design security not possible in sram-based fpgas. the option to program these fuses is selectable via quickworks in the tools/options/device programming window in spde. flexibility fuse the flexibility link enables power-up loading of the embedded ram blocks. if the link is programmed, the power up loading state machine is activated during power-up of the device. the state machine communicates with an external eprom via the jtag pins to download memory contents into the on-chip ram. if the link is not programmed, power-up loadin g is not enabled and the jtag pins function as they normally would. the option to program this bit is selectable via qu ickworks in the tools/options/device programming window in spde. for more information on power-up loading refer to quicklogic application note 55 at http://www.quicklogic.com /images/appnote55.pdf .
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 17 jtag pin descriptions note: all jtag inputs are clamped to the v cc rail, not the v ccio . therefore, these pins can only be driven up to v cc + 0.3 v. these input pins are lvcmos2 compliant only (2.5 v). all jtag outputs are driven by the v cc rail, not v ccio . therefore, these output pins can only drive up to v cc + 0.3 v. these output pins are lvcmos2 compliant only (2.5 v). table 7: jtag pin descriptions pin function description tdi/rsi test data in for jtag/ram init. serial data in hold high during normal operation. connects to serial prom data in for ram initialization. connect to vcc if unused trstb/rro active low reset for jtag/ram init. reset out hold low during normal operation. connects to serial prom reset for ram initialization. connect to gnd if unused tms test mode select for jtag hold high during normal operation. connect to v cc if not used for jtag tck test clock for jtag hold high or low during normal operation. connect to v cc or ground if not used for jtag tdo/rco test data out for jtag/ram init. clock out connect to serial prom clock for ram initialization. must be left unconnected if not used for jtag or ram initialization
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 18 electrical specifications dc characteristics the dc specifications are provided in table 8 through table 12 . table 8: absolute maximum ratings parameter value parameter value v cc voltage -0.5 v to 3.6 v dc input current 20 ma v ccio voltage -0.5 v to 4.6 v esd pad protection 2000 v inref voltage 2.7 v leaded package storage temperature -65 c to + 150 c input voltage a a. all dedicated inputs including the clk, dedclk, p llin, pllrst, and ioctrl pins, are clamped to the v cc rail, not the v ccio . therefore, these pins can only be driven up to v cc + 0.3 v. these input pins are lvcmos2 compliant only (2.5 v). -0.5 v to v ccio +0.5 v laminate package (bga) storage temperature -55 c to + 125 c latch-up immunity 100 ma table 9: operating range symbol parameter military industrial commercial unit min. max. min. max. min. max. v cc supply voltage 2.3 2.7 2.3 2.7 2.3 2.7 v v ccio i/o input tolerance voltage 2.3 3.6 2.3 3.6 2.3 3.6 v ta ambient temperature -55 -40 85 0 70 c tc case temperature - 125 - - - - c k delay factor -4 speed grade 0.42 2.3 0.43 2.16 0.47 2.11 n/a -5 speed grade 0.42 1.92 0.43 1.80 0.46 1.76 n/a -6 speed grade 0.42 1.35 0.43 1.26 0.46 1.23 n/a -7 speed grade 0.42 1.27 0.43 1.19 0.46 1.16 n/a
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 19 note: if plls are not used, the v cc pll and pllrst pins may be grounded to the lower i cc for the device. note: the data provided in table 12 are jedec and pci specifications. quicklogic devices either meet or exceed these requirements. note: all dedicated inputs including th e clk, dedclk, pllin, pllrst, and ioctrl pins, are clamped to the v cc rail, not the v ccio . therefore, these pins can only be driven up to v cc + 0.3 v. these input pins are lvcmos2 compliant only (2.5 v). table 10: dc characteristics symbol parameter conditions min. max. unit i i i or i/o input leakage current v i = v ccio or gnd -10 10 a i oz 3-state output leakage current v i = v ccio or gnd -10 10 a c i input capacitance a a. capacitance is sample tested only. clock pins are 12 pf maximum. --8pf i os output short circuit current b b. only one output at a time. duration should not exceed 30 seconds. v o = gnd v o = v cc -15 40 -180 210 ma ma i cc d.c. supply current c c. for -4/-5/-6/-7 commerc ial grade devices only. see table 11 for more details on i cc characteristics. v i, v o = v ccio or gnd 0.50 (typ) 2 ma i ccio d.c. supply current on v ccio - 0 2 ma i ccio (dif) d.c. supply current on v ccio for differential i/o ---ma i ref d.c. supply current on inref - -10 10 a i pd pad pull-down (programmable) v ccio = 3.6 v - 150 a table 11: i cc characteristics characteristic condition temperature commercial industrial military i cc v cc pll = gnd 2 ma (max) 3 ma (max) 5 ma (max) v cc pll = v cc 3.25 ma (max) 5 ma (max) 10 ma (max) table 12: dc input and output levels inref v il v ih v ol v oh i ol i oh v min v max v min v max v min v max v max v min ma ma lvttl n/a n/a -0.3 0.8 2.0 v ccio + 0.3 0.4 2.4 2.0 -2.0 lv c m o s 2 n/a n/a -0.3 0.7 1.7 v ccio + 0.3 0.7 1.7 2.0 -2.0 gtl+ 0.88 1.12 -0.3 inref - 0.2 inref + 0.2 v ccio + 0.3 0.6 n/a 40 n/a pci n/a n/a -0.3 0.3 x v ccio 0.5 x v ccio v ccio + 0.5 0.1 x v ccio 0.9 x v ccio 1.5 -0.5 sstl2 1.15 1.35 -0.3 inref - 0.18 inref + 0.18 v ccio + 0.3 0.74 1.76 7.6 -7.6 sstl3 1.3 1.7 -0.3 inref - 0.2 inref + 0.2 v ccio + 0.3 1.10 1.90 8 -8
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 20 i/o characteristics figure 14: iol vs. vol figure 15: ioh vs. voh iol v s vol 0 20 40 60 80 100 120 140 160 180 0.00 0.20 0.40 0.60 0.80 1.00 1.20 1.40 1.60 1.80 2.00 2.20 2.40 2.60 2.80 3.00 supply voltage (v) current (ma) vccio = 3.6v vccio = 3.3v vccio = 3.0v vccio = 2.7v vccio = 2.5v vccio = 2.3v -120 -100 -80 -60 -40 -20 0 20 0.00 0.10 0.30 0.50 0.70 0. 90 1.10 1.30 1.50 1.70 1.90 2.10 2.30 2.50 2. 70 2.90 3.00 3.10 3. 30 3.50 3.60 supply voltage (v) current (ma) vcci/o = 2.3v vcci/o = 2.5v vcci/o = 2.7v vcci/o = 3.3v vcci/o = 3.6v vcci/0 = 3.0v ioh v s voh
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 21 ac characteristics at v cc = 2.5 v, ta = 25 c (k = 1.00) the ac specifications are provided from table 13 to table 21 . logic cell diagrams and waveforms are provided from figure 16 to figure 21 . figure 16: eclipse logic cell table 13: logic cells symbol parameter value min. max. t pd combinatorial delay of the longest path: time taken by the combinatorial circuit to output 0.205 ns 1.01 ns t su setup time: time the synchronous input of the f lip flop must be stable before the active clock edge 0.231 ns - t hl hold time: time the synchronous input of the f lip flop must be stable after the active clock edge 0 ns - t co clock to out delay: the amount of time taken by t he flip flop to output after the active clock edge. - 0.427 ns t cwhi clock high time: required minimum time the clock stays high 0.46 ns - t cwlo clock low time: required minimum time that the clock stays low 0.46 ns - t set set delay: time between when the flip flop is ?set? (high) and when the output is consequently ?set? (high) - 0.585 ns t reset reset delay: time between when the flip flop is ?reset? (low) and when the output is consequently ?reset? (low) - 0.658 ns t sw set width: time that the set signal remains high/low 0.3 ns - t rw reset width: time that the reset signal remains high/low 0.3 ns -
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 22 figure 17: logic cell flip flop figure 18: logic cell flip flop timings - first waveform figure 19: logic cell flip flop timings - second waveform set d clk reset q set reset q clk t cwhi (min) t cwlo (min) t reset t rw t set t sw clk d q t su t hl t co
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 23 figure 20: eclipse global clock structure figure 21: global clock structure schematic table 14: eclipse global clock tree delays clock segment parameter value max. rise max. fall t pgck global clock pin delay to quad net 0.990 ns 1.386 ns t bgck global clock buffer delay (quad net to flip flop) 0.534 ns 1.865 ns quad net programmable clock external clock global clock buffer global clock t pgck t bgck clock select
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 24 figure 22: ram module table 15: ram cell synchronous write timing symbol parameter value min. max. ram cell synchronous write timing t swa wa setup time to wclk: time the write address must be stable before the active edge of the write clock 0.675 ns - t hwa wa hold time to wclk: time the write address must be stable after the active edge of the write clock 0 ns - t swd wd setup time to wclk: time the write data must be stable before the active edge of the write clock 0.654 ns - t hwd wd hold time to wclk: time the write data must be stable afte r the active edge of the write clock 0 ns - t swe we setup time to wclk: time the write enable must be stable before the active edge of the write clock 0.276 ns - t hwe we hold time to wclk: time the write enable must be stable after the active edge of the write clock 0 ns - t wcrd wclk to rd (wa = ra): time between the active write clock edge and the time when the data is available at rd - 2.796 ns wa wd we wclk re rclk ra rd ram mod ule [9:0] [17:0] [9:0] [17:0] asyncrd
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 25 figure 23: ram cell synchronous write timing table 16: ram cell synchronous and asynchronous read timing symbol parameter value min. max. ram cell synchronous read timing t sra ra setup time to rclk: time the read address must be stable before the active edge of the read clock 0.686 ns - t hra ra hold time to rclk: time the read address must be stable after the active edge of the read clock 0 ns - t sre re setup time to wclk: time the read enable must be stable before the active edge of the read clock 0.243 ns - t hre re hold time to wclk: time the read enable must be stable after the active edge of the read clock 0 ns - t rcrd rclk to rd: time between the active read clock edge and the time when the data is available at rd - 2.225 ns ram cell asynchronous read timing r pdrd ra to rd: time between when the read address is input and when the data is output - 2.405 ns t swa t swd t swe t hwa t hwd t hwe t wcrd old data new data wclk wa wd we rd
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 26 figure 24: ram cell synchronous and asynchronous read timing figure 25: eclipse cell i/o t sra t hra rclk ra t sre t hre t rcrd old data new data re rd r pdrd e r q d r q e r q d + - pad output enable register output register input register d
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 27 figure 26: eclipse input register cell table 17: input register cell symbol parameter value min. max. t isu input register setup time: time the synchronous input of the pin must be stable before the active clock edge 3.308 ns 3.526 ns t ihl input register hold time: time the synchronous input of the flip-flop must be stable after the active clock edge 0 ns - t ico input register clock to out: time taken by the flip-flop to output after the active clock edge - 0.494 ns t irst input register reset delay: time between when the flip-flop is ?reset? (low) and when the output is consequently ?reset? (low) - 0.464 ns t iesu input register clock enable setup time: time ?enable? must be stable before the active clock edge 0.830 ns 0.987 ns t ieh input register clock enable hold time: time ?enable? must be stable after the active clock edge 0 ns - pad t in ,t ini t iclk t isu t sid + - q e d r
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 28 figure 27: eclipse input register cell timing table 18: standard input delays symbol parameter value to get the total input de lay add this delay to t isu min. max. t sid (lvttl) lvttl input delay: low voltage ttl for 3.3 v applications - 0.34 ns t sid (lvcmos2) lvcmos2 input delay: low voltage cmos for 2.5 v and lower applications - 0.42 ns t sid (gtl+) gtl+ input delay: gunning transceiver logic - 0.68 ns t sid (sstl3) sstl3 input delay: stub series terminated logic for 3.3 v - 0.55 ns t sid (sstl2) sstl2 input delay: stub series terminated logic for 2.5 v - 0.61 ns r clk d q t isu t ihl t ico t iesu t ieh t irst e
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 29 figure 28: eclipse output register cell table 19: eclipse output register cell symbol parameter value output register cell only min. max. t outlh output delay low to high (90% of h) - 2.594 ns t outhl output delay high to low (10% of l) - 2.163 ns t pzh output delay tri-state to high (90% of h) - 3.056 ns t pzl output delay tri-state to low (10% of l) - 2.709 ns t phz output delay high to tri-state - 3.434 ns t plz output delay low to tri-state - 3.318 ns t cop clock to out delay (does not include clock tree delays) - 2.667 ns (fast slew) 8.999 ns (slow slew) pad output register
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 30 figure 29: eclipse output register cell timing note: for tips to minimize ground bounce, refer to application note 66 at http://www.quicklogic.com /images/appnote66.pdf . table 20: output slew rates @ v ccio = 3.3 v fast slew slow slew rising edge 2.8 v/ns 1.0 v/ns falling edge 2.86 v/ns 1.0 v/ns table 21: output slew rates @ v ccio = 2.5 v fast slew slow slew rising edge 1.7 v/ns 0.6 v/ns falling edge 1.9 v/ns 0.6 v/ns l h l h t outlh t outhl l h z t pzh l h z t pzl l h z t plz l h z t phz
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 31 package thermal characteristics thermal resistance equations: jc = (t j - t c )/p ja = (tj - ta)/p p max = (t jmax - t amax )/ ja parameter description: jc : junction-to-case thermal resistance ja : junction-to-ambient thermal resistance t j : junction temperature t a : ambient temperature p: power dissipated by the device while operating p max : the maximum power dissipation for the device t jmax : maximum junction temperature t amax : maximum ambient temperature note: maximum junction temperature (t jmax ) is 150c. to calculate the maximum power dissipation for a device package look up ja from table 22 , pick an appropriate t amax and use: p max = (150oc - t amax )/ ja table 22: package thermal characteristics package description ja (o c/w) @ various flow rates (m/sec) jc (o c/w) pin count package type 0 0.5 1 2 516 pbga 20.0 19.0 17.5 16.0 7.0 484 pbga 28.0 26.0 25.0 23.0 9.0 280 lfbga 18.5 17.0 15.5 14.0 7.0 208 pqfp 26.0 24.5 23.0 22.0 11.0
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 32 kv and kt graphs figure 30: voltage factor vs. supply voltage figure 31: temperature factor vs. operating temperature voltage factor vs. supply voltage 0.9200 0.9400 0.9600 0.9800 1.0000 1.0200 1.0400 1.0600 1.0800 1.1000 2.25 2.3 2.35 2.4 2.45 2.5 2.55 2.6 2.65 2.7 2.75 supply voltage (v) kv temperature factor vs. operating temperature 0.85 0.90 0.95 1.00 1.05 1.10 1.15 -60 -40 -20 0 20 40 60 80 junction temperature c kt
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 33 power vs. operating frequency the basic power equation which best mo dels power consumption is given below: p total = 0.350 + f [0.0031 lc + 0.0948 ckbf + 0.01 clbf + 0.0263 ckld + 0.543 ram + 0.20 pll + 0.0035 inp + 0.0257 outp ] (mw) where: lc is the total number of logic cells in the design ckbf = # of clock buffers clbf = # of column clock buffers ckld = # of loads connected to the column clock buffers ram = # of ram blocks pll = # of plls inp is the number of input pins outp is the number of output pins figure 32 exhibits the power consumption in an eclipse device. the chip was filled with (300) 8-bit counters (approximately 76% logi c cell utilization). figure 32: power consumption power vs freq. (counter_300) 0 0.5 1 1.5 2 2.5 0 20 40 60 80 100 120 140 frequency (mhz) power (w)
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 34 figure 33 illustrates the theoretical wo rst-case scenarios for 50%, 70%, and 90% utilizations of the ql6600- 516 package. the resources of the device are divided e xactly in half; meaning, for 50% utilization, exactly 50% of the i/os, logic cells, ram bloc ks, clock network, etc. are utilized . these situations may never occur in a real design, but they do provide a very rough quan titative measure of power consumption when talking in terms of 50% or 70% utilization of an eclipse device. figure 33: power vs. frequency (absolute 50%, 70%, and 90% of the available resources on chip) to learn more about power consumption, refer to application note 60 which is located at http://www.quicklogic.com /images/appnote60.pdf . power vs. frequency 0 1 2 3 4 5 6 7 0 50 100 150 200 250 300 frequency (mhz) 50% 70% 90% power (mw)
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 35 power-up sequencing figure 34: power-up requirements/recommendations when powering up a device, the v cc /v ccio rails must take 400 s or long er to reach the maximum value (refer to figure 34 ). note: ramping v cc /v ccio to the maximum voltage faster than 400 s can cause the device to behave improperly. for users with a limited power budget, keep (v ccio -v cc ) max 500 mv when ramping up the power supply. voltage v ccio v cc (v ccio -v cc ) max 400 us v cc
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 36 pin descriptions table 23 describes the pins/balls of all eclipse devices. table 23: dedicated pin descriptions pin direction function description clk a a. all dedicated inputs including the clk, dedclk, pl lin, pllrst, and ioctrl pins, are clamped to the v cc rail, not the v ccio . therefore, these pins can only be driven up to v cc + 0.3 v. these input pins are lvcmos2 compliant only (2.5 v). i global clock network driver low skew global clock. this pin provides access to a dedicated, distributed network capable of driving the clock, set, reset, f1, and a2 inputs to the logic cell, read and write clocks, read and write enables of the embedded ram blocks, and output enables of the i/os. i/o(a) i/o input/output pin the i/o pin is a bi-directional pin, configurable to either an input-only, output-only, or bi-directional pin. t he a inside the parenthesis means that the i/o is located in bank a. if an i/o is not used, spde (quick works tool) provides the option of tying that pin to gnd, v cc, or tristate during programming. v cc i power supply pin connect to 2.5 v supply. v ccio (a) i input voltage tolerance pin this pin provides the flexibility to interface the device with either a 3.3 v device or a 2.5 v device. the a in side the parenthesis means that v ccio is located in bank a. every i/o pin in bank a will be tolerant of v ccio input signals and will output v ccio level signals. this pin must be connected to either 3.3 v or v cc . v cc pll b b. all pllout output pins are driven by the v cc rail, not the v ccio rail. these output pins are lv cmos2 compliant only (2.5 v). i phase locked loop power supply pin connect to 2.5 v supply. vccpll should be connected to 2.5 v supply if the plls are used. if the plls are not used, v cc pll can be connected to 2.5 v supply or gnd. see table 11 for i cc differences when v cc pll is connected to 2.5 v or gnd. gnd i ground pin connect to ground. pllin a i pll clock input clock input for pll. dedclk a i dedicated clock pin low skew global clock. this pin provides access to a dedicated, distributed clock network capable of driving the clock inputs of all sequential elements of the device (e.g., ram and flip-flops). gndpll i ground pin for pll connect to gnd. inref(a) i differential reference voltage the inref is the reference voltag e pin for gtl+, sstl2, and sttl3 standards. follow the recommendations provided in table 18 for the appropriate standard. the a inside t he parenthesis means that inref is located in bank a. this pin should be tied to gnd if not needed. pllout b o pll output pin dedicated pll output pin. otherwise may be left unconnected. pllrst a i reset input pin for pll reset input for pll. if plls are not used, pllrst should be connected to the same voltage as v cc pll (e.g., v cc or gnd). ioctrl(a) a i highdrive input this pin provides fast reset, set , clock, and enable access to the i/o cell flip-flops, providing fast cloc k-to-out and fast i/o response times. this pin can also double as a high-drive pin to the internal logic cells. the a inside the parenthesis means that ioct rl is located in bank a. this pin should be tied to gnd or v cc if it is not used.
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 37 figure 35: i/o banks with relevant pins recommended unused pin terminations for the eclipse devices all unused, general purpose i/ o pins can be tied to v cc , gnd, or hiz (high impedance) internally using the configuration editor. this option is given in the botto m-right corner of the placement window. to use the placement editor, choose constraint ? fix placement in the option pull-down menu of spde. the rest of the pins should be terminated at the board level in the manner presented in table 24 . note: x -> number, y -> alphabetical character. table 24: recommended unused pin terminations signal name recommended termination pllout for low power unused pll output pins can be connected to v cc or gnd so that their associated input buffer never floats, otherwise pll output pi ns can be left unconnect ed. utilized pll output pins that route the pll clock outside of t he chip should not be tied to either v cc or gnd. ioctrl any unused pins of this type must be connected to either v cc or gnd. clk/pllin any unused clock pins should be connected to v cc or gnd. pllrst if a pll module is not used, then the asso ciated pllrst must be connected to v cc ; under normal operation, use it as needed. if plls ar e not used, the associated pllrst pin must be connected to the same voltage as v cc pll (2.5 v or gnd). inref if an i/o bank does not require the use of inref signal the pin should be connected to gnd. io bank a io bank b v ccio (a) inref(a) ioctrl(a) io(a) v ccio (a) inref(a) ioctrl(a) io(a) io bank c io bank d v ccio (c) inref(c) ioctrl(c) io(c) v ccio (d) inref(d) ioctrl(d) io(d) io bank f io bank e v ccio (f) inref(f) ioctrl(f) io(f) v ccio (e) inref(e) ioctrl(e) io(e) io bank h io bank g (h) inref(h) ioctrl(h) io(h) v ccio v ccio (g) inref(g) ioctrl(g) io(g)
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 38 ql6250 - 208 pqfp pinout diagram eclipse ql6250-4pq208c
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 39 ql6250 - 208 pqfp pinout table table 25: 208 pqfp pinout table pin function pin function pin function pin function pin function 1 pllrst(3) 43 io(b) 85 io(d) 127 clk(5)/pllin(3) 169 ioctrl(g) 2 vccpll(3) 44 vccio(b) 86 vcc 128 clk(6) 170 inref(g) 3 gnd 45 io(b) 87 io(d) 129 vcc 171 ioctrl(g) 4 gnd 46 vcc 88 io(d) 130 clk(7) 172 io(g) 5 io(a) 47 io(b) 89 vcc 131 vcc 173 io(g) 6 io(a) 48 io(b) 90 io(d) 132 clk(8) 174 io(g) 7 io(a) 49 gnd 91 io(d) 133 tms 175 vcc 8 vccio(a) 50 tdo 92 ioctrl(d) 134 io(f) 176 io(g) 9 io(a) 51 pllout(1) 93 inref(d) 135 io(f) 177 vccio(g) 10 io(a) 52 gndpll(2) 94 ioctrl(d) 136 io(f) 178 gnd 11 ioctrl(a) 53 gnd 95 io(d) 137 gnd 179 io(g) 12 vcc 54 vccpll(2) 96 io(d) 138 vccio(f) 180 io(g) 13 inref(a) 55 pllrst(2) 97 io(d) 139 io(f) 181 io(g) 14 ioctrl(a) 56 vcc 98 vccio(d) 140 io(f) 182 vcc 15 io(a) 57 io(c) 99 io(d) 141 io(f) 183 tck 16 io(a) 58 gnd 100 io(d) 142 io(f) 184 vcc 17 io(a) 59 io(c) 101 gnd 143 io(f) 185 io(h) 18 io(a) 60 vccio(c) 102 pllout(0) 144 ioctrl(f) 186 io(h) 19 vccio(a) 61 io(c) 103 gnd 145 inref(f) 187 io(h) 20 io(a) 62 io(c) 104 gndpll(1) 146 vcc 188 gnd 21 gnd 63 io(c) 105 pllrst(1) 147 ioctrl(f) 189 vccio(h) 22 io(a) 64 io(c) 106 vccpll(1) 148 io(f) 190 io(h) 23 tdi 65 io(c) 107 io(e) 149 io(f) 191 io(h) 24 clk(0) 66 io(c) 108 gnd 150 vccio(f) 192 ioctrl(h) 25 clk(1) 67 ioctrl(c) 109 io(e) 151 io(f) 193 io(h) 26 vcc 68 inref(c) 110 io(e) 152 io(f) 194 inref(h) 27 clk(2)/pllin(2) 69 ioctrl(c) 111 vccio(e) 153 gnd 195 vcc 28 clk(3)/pllin(1) 70 io(c) 112 io(e) 154 io(f) 196 ioctrl(h) 29 vcc 71 io(c) 113 vcc 155 pllout(3) 197 io(h) 30 clk(4)/ dedclk/pllin(0) 72 vccio(c) 114 io(e) 156 gndpll(0) 198 io(h) 31 io(b) 73 io(c) 115 io(e) 157 gnd 199 io(h) 32 io(b) 74 io(c) 116 io(e) 158 vccpll(0) 200 io(h) 33 gnd 75 gnd 117 ioctrl(e) 159 pllrst(0) 201 io(h) 34 vccio(b) 76 vcc 118 inref(e) 160 gnd 202 io(h) 35 io(b) 77 io(c) 119 ioctrl(e) 161 io(g) 203 vccio(h) 36 io(b) 78 trstb 120 io(e) 162 vccio(g) 204 gnd 37 io(b) 79 vcc 121 io(e) 163 io(g) 205 io(h) 38 io(b) 80 io(d) 122 vccio(e) 164 io(g) 206 pllout(2) 39 ioctrl(b) 81 io(d) 123 gnd 165 vcc 207 gnd 40 inref(b) 82 io(d) 124 io(e) 166 io(g) 208 gndpll(3) 41 ioctrl(b) 83 gnd 125 io(e) 167 io(g) 42 io(b) 84 vccio(d) 126 io(e) 168 io(g)
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 40 ql6250 - 280 lfbga pinout diagram top bottom eclipse ql6250-4pt280c pin a1 corner
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 41 ql6250 - 280 lfbga pinout table table 26: 280 lfbga pinout table ball function ball function ball function ball function ball function ball function a1 pllout(3) c10 clk(5)/ pllin(3) e19 ioctrl(d) k16 i/o(c) r4 i/o(h) u13 i/o(b) a2 gndpll(0) c11 vccio(e) f1 inref(g) k17 i/o(d) r5 gnd u14 ioctrl(b) a3 i/o(f) c12 i/o(e) f2 ioctrl(g) k18 i/o(c) r6 gnd u15 vccio(b) a4 i/o(f) c13 i/o(e) f3 i/o(g) k19 trstb r7 vcc u16 i/o(b) a5 i/o(f) c14 i/o(e) f4 i/o(g) l1 i/o(h) r8 vcc u17 tdo a6 ioctrl(f) c15 vccio(e) f5 gnd l2 i/o(h) r9 gnd u18 pllrst(2) a7 i/o(f) c16 i/o(e) f15 vcc l3 vccio(h) r10 gnd u19 i/o(b) a8 i/o(f) c17 i/o(e) f16 ioctrl(d) l4 i/o(h) r11 vcc v1 pllout(2) a9 i/o(f) c18 i/o(e) f17 i/o(d) l5 vcc r12 vcc v2 gndpll(3) a10 clk(7) c19 i/o(e) f18 i/o(d) l15 gnd r13 vcc v3 gnd a11 i/o(e) d1 i/o(g) f19 i/o(d) l16 i/o(c) r14 vcc v4 i/o(a) a12 i/o(e) d2 i/o(g) g1 i/o(g) l17 vccio(c) r15 gnd v5 i/o(a) a13 i/o(e) d3 i/o(f) g2 i/o(g) l18 i/o(c) r16 i/o(c) v6 ioctrl(a) a14 ioctrl(e) d4 i/o(f) g3 ioctrl(g) l19 i/o(c) r17 vccio(c) v7 i/o(a) a15 i/o(e) d5 i/o(f) g4 i/o(g) m1 i/o(h) r18 i/o(c) v8 i/o(a) a16 i/o(e) d6 i/o(f) g5 vcc m2 i/o(h) r19 i/o(c) v9 i/o(a) a17 i/o(e) d7 i/o(f) g15 vcc m3 i/o(h) t1 i/o(h) v10 clk(1) a18 pllrst(1) d8 i/o(f) g16 i/o(d) m4 i/o(h) t2 i/o(h) v11 clk(4)/ dedclk/ pllin(0) a19 gnd d9 clk(8) g17 i/o(d) m5 vcc t3 i/o(a) v12 i/o(b) b1 pllrst(0) d10 i/o(e) g18 i/o(d) m15 vcc t4 i/o(a) v13 i/o(b) b2 gnd d11 i/o(e) g19 i/o(d) m16 inref(c) t5 i/o(a) v14 inref(b) b3 i/o(f) d12 i/o(e) h1 i/o(g) m17 i/o(c) t6 ioctrl(a) v15 i/o(b) b4 i/o(f) d13 inref(e) h2 i/o(g) m18 i/o(c) t7 i/o(a) v16 i/o(b) b5 i/o(f) d14 i/o(e) h3 i/o(g) m19 i/o(c) t8 i/o(a) v17 i/o(b) b6 inref(f) d15 i/o(e) h4 i/o(g) n1 ioctrl(h) t9 i/o(a) v18 gndpll(2) b7 i/o(f) d16 i/o(d) h5 vcc n2 i/o(h) t10 i/o(a) v19 gnd b8 i/o(f) d17 i/o(d) h15 vcc n3 i/o(h) t11 clk(3)/ pllin(1) w1 gnd b9 tms d18 i/o(d) h16 vcc n4 i/o(h) t12 i/o(b) w2 pllrst(3) b10 clk(6) d19 i/o(d) h17 i/o(d) n5 vcc t13 i/o(b) w3 i/o(a) b11 i/o(e) e1 i/o(g) h18 i/o(d) n15 vcc t14 i/o(b) w4 i/o(a) b12 i/o(e) e2 i/o(g) h19 i/o(d) n16 i/o(c) t15 i/o(b) w5 i/o(a) b13 ioctrl(e) e3 vccio(g) j1 i/o(g) n17 i/o(c) t16 i/o(b) w6 i/o(a) b14 i/o(e) e4 i/o(f) j2 i/o(g) n18 ioctrl(c) t17 vccpll(2) w7 i/o(a) b15 i/o(e) e5 gnd j3 vccio(g) n19 ioctrl(c) t18 i/o(b) w8 i/o(a) b16 i/o(e) e6 vcc j4 i/o(g) p1 i/o(h) t19 i/o(b) w9 tdi b17 vccpll(1) e7 vcc j5 gnd p2 i/o(h) u1 i/o(a) w10 clk(2)/ pllin(2) b18 gndpll(1) e8 vcc j15 vcc p3 ioctrl(h) u2 i/o(a) w11 i/o(b) b19 pllout(0) e9 vcc j16 i/o(c) p4 inref(h) u3 vccpll(3) w12 i/o(b) c1 i/o(f) e10 gnd j17 vccio(d) p5 vcc u4 i/o(a) w13 i/o(b) c2 vccpll(0) e11 gnd j18 i/o(d) p15 gnd u5 vccio(a) w14 ioctrl(b) c3 i/o(f) e12 vcc j19 i/o(d) p16 i/o(c) u6 inref(a) w15 i/o(b) c4 i/o(f) e13 vcc k1 vcc p17 i/o(c) u7 i/o(a) w16 i/o(b) c5 vccio(f) e14 gnd k2 tck p18 i/o(c) u8 i/o(a) w17 i/o(b) c6 ioctrl(f) e15 gnd k3 i/o(g) p19 i/o(c) u9 vccio(a) w18 i/o(b) c7 i/o(f) e16 i/o(d) k4 i/o(g) r1 i/o(h) u10 clk(0) w19 pllout(1) c8 i/o(f) e17 vccio(d) k5 gnd r2 i/o(h) u11 vccio(b) c9 vccio(f) e18 inref(d) k15 gnd r3 vccio(h) u12 i/o(b)
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 42 ql6250 - 484 pbga pinout diagram top bottom eclipse ql6250-4ps484c 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 a b c e d f g h k j l m n r p t u v y w 22 21 a b aa pin a1 corner pin a1
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 43 ql6250 - 484 pbga pinout table table 27: 484 pbga pinout table ball function ball function ball function ball function ball function ball function a1 nc c1 nc e1 ioctrl(a) g1 nc j1 i/o(a) l1 clk(4)/ dedclk/ pllin(0) a2 pllrst(3) c2 i/o(a) e2 i/o(a) g2 nc j2 i/o(a) l2 clk(0) a3 i/o(a) c3 vccpll(3) e3 i/o(a) g3 i/o(a) j3 i/o(a) l3 clk(2)/pllin(2) a4 i/o(a) c4 pllout(2) e4 i/o(a) g4 i/o(a) j4 i/o(a) l4 i/o(a) a5 i/o(a) c5 i/o(a) e5 nc g5 i/o(a) j5 i/o(a) l5 i/o(a) a6 nc c6 nc e6 i/o(h) g6 i/o(a) j6 i/o(a) l6 i/o(a) a7 i/o(h) c7 i/o(h) e7 nc g7 gnd j7 i/o(a) l7 gnd a8 ioctrl(h) c8 nc e8 i/o(h) g8 i/o(h) j8 vcc l8 gnd a9 i/o(h) c9 ioctrl(h) e9 i/o(h) g9 i/o(h) j9 gnd l9 gnd a10 nc c10 nc e10 i/o(h) g10 nc j10 vcc l10 gnd a11 nc c11 i/o(h) e11 vded2 g11 i/o(g) j11 vcc l11 gnd a12 tck c12 nc e12 i/o(g) g12 gnd j12 gnd l12 gnd a13 i/o(g) c13 i/o(g) e13 i/o(g) g13 nc j13 vcc l13 gnd a14 i/o(g) c14 nc e14 nc g14 nc j14 gnd l14 vcc a15 i/o(g) c15 i/o(g) e15 ioctrl(g) g15 i/o(g) j15 vcc l15 vcc a16 nc c16 i/o(g) e16 i/o(g) g16 gnd j16 i/o(f) l16 clk(6) a17 i/o(g) c17 nc e17 inref(g) g17 vccio(f) j17 vccio(f) l17 vccio(f) a18 i/o(g) c18 i/o(g) e18 nc g18 i/o(f) j18 i/o(f) l18 i/o(f) a19 i/o(f) c19 i/o(f) e19 i/o(f) g19 i/o(f) j19 i/o(f) l19 clk(8) a20 gnd c20 gndpll(0) e20 i/o(f) g20 i/o(f) j20 i/o(f) l20 i/o(f) a21 pllout(3) c21 i/o(f) e21 nc g21 inref(f) j21 i/o(f) l21 nc a22 i/o(f) c22 i/o(f) e22 i/o(f) g22 i/o(f) j22 i/o(f) l22 i/o(f) b1 i/o(a) d1 i/o(a) f1 i/o(a) h1 i/o(a) k1 tdi m1 i/o(b) b2 gnd d2 i/o(a) f2 inref(a) h2 i/o(a) k2 i/o(a) m2 i/o(b) b3 gndpll(3) d3 i/o(a) f3 nc h3 i/o(a) k3 i/o(a) m3 i/o(b) b4 gnd d4 i/o(a) f4 i/o(a) h4 i/o(a) k4 i/o(a) m4 clk(3)/pllin(1) b5 i/o(a) d5 i/o(a) f5 i/o(a) h5 ioctrl(a) k5 i/o(a) m5 nc b6 i/o(h) d6 i/o(h) f6 vccio(a) h6 vccio(a) k6 vccio(a) m6 vccio(b) b7 i/o(h) d7 nc f7 vccio(h) h7 i/o(h) k7 nc m7 clk(1) b8 inref(h) d8 i/o(h) f8 i/o(h) h8 gnd k8 vcc m8 vcc b9 i/o(h) d9 nc f9 vccio(h) h9 vcc k9 vcc m9 vcc b10 i/o(h) d10 i/o(h) f10 i/o(h) h10 vcc k10 gnd m10 gnd b11 i/o(h) d11 i/o(h) f11 vccio(h) h11 vded k11 gnd m11 gnd b12 nc d12 i/o(g) f12 vccio(g) h12 gnd k12 gnd m12 gnd b13 nc d13 i/o(g) f13 i/o(g) h13 vcc k13 gnd m13 gnd b14 nc d14 i/o(g) f14 vccio(g) h14 vcc k14 vcc m14 gnd b15 nc d15 ioctrl(g) f15 nc h15 gnd k15 vcc m15 gnd b16 i/o(g) d16 i/o(g) f16 vccio(g) h16 i/o(f) k16 nc m16 gnd b17 i/o(g) d17 i/o(g) f17 nc h17 i/o(f) k17 i/o(f) m17 i/o(e) b18 i/o(g) d18 i/o(f) f18 i/o(f) h18 nc k18 i/o(f) m18 i/o(e) b19 pllrst(0) d19 vccpll(0) f19 i/o(f) h19 i/o(f) k19 nc m19 i/o(e) b20 i/o(f) d20 i/o(f) f20 ioctrl(f) h20 i/o(f) k20 i/o(f) m20 clk(7) b21 i/o(f) d21 i/o(f) f21 i/o(f) h21 i/o(f) k21 i/o(f) m21 clk(5)/pllin(3) b22 i/o(f) d22 i/o(f) f22 ioctrl(f) h22 nc k22 nc m22 tms
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 44 n1 nc p16 i/o(e) t9 nc v2 i/o(b) w17 nc aa10 i/o(c) n2 i/o(b) p17 nc t10 trstb v3 i/o(b) w18 i/o(e) aa11 i/o(c) n3 i/o(b) p18 i/o(e) t11 gnd v4 i/o(b) w19 nc aa12 i/o(d) n4 nc p19 nc t12 nc v5 i/o(b) w20 i/o(e) aa13 i/o(d) n5 i/o(b) p20 i/o(e) t13 i/o(d) v6 nc w21 nc aa14 i/o(d) n6 nc p21 i/o(e) t14 nc v7 i/o(c) w22 i/o(e) aa15 i/o(d) n7 nc p22 i/o(e) t15 i/o(d) v8 i/o(c) y1 i/o(b) aa16 nc n8 vcc r1 i/o(b) t16 gnd v9 nc y2 i/o(b) aa17 nc n9 vcc r2 inref(b) t17 i/o(e) v10 i/o(c) y3 vccpll(2) aa18 i/o(d) n10 gnd r3 i/o(b) t18 i/o(e) v11 nc y4 i/o(c) aa19 i/o(e) n11 gnd r4 i/o(b) t19 nc v12 vded2 y5 i/o(c) aa20 gndpll(1) n12 gnd r5 i/o(b) t20 nc v13 nc y6 i/o(c) aa21 i/o(e) n13 gnd r6 nc t21 ioctrl(e) v14 i/o(d) y7 i/o(c) aa22 i/o(e) n14 vcc r7 i/o(b) t22 i/o(e) v15 i/o(d) y8 ioctrl(c) ab1 i/o(b) n15 vcc r8 gnd u1 ioctrl(b) v16 inref(d) y9 i/o(c) ab2 gndpll(2) n16 i/o(e) r9 vcc u2 i/o(b) v17 i/o(d) y10 i/o(c) ab3 pllrst(2) n17 vccio(e) r10 vcc u3 ioctrl(b) v18 i/o(e) y11 i/o(d) ab4 i/o(b) n18 i/o(e) r11 gnd u4 i/o(b) v19 i/o(e) y12 nc ab5 i/o(b) n19 i/o(e) r12 vded u5 i/o(b) v20 i/o(e) y13 nc ab6 i/o(c) n20 i/o(e) r13 vcc u6 i/o(c) v21 i/o(e) y14 i/o(d) ab7 i/o(c) n21 i/o(e) r14 vcc u7 vccio(c) v22 i/o(e) y15 ioctrl(d) ab8 ioctrl(c) n22 i/o(e) r15 gnd u8 nc w1 i/o(b) y16 i/o(d) ab9 i/o(c) p1 nc r16 i/o(d) u9 vccio(c) w2 i/o(b) y17 i/o(d) ab10 i/o(c) p2 i/o(b) r17 vccio(e) u10 i/o(c) w3 i/o(b) y18 i/o(e) ab11 nc p3 i/o(b) r18 i/o(e) u11 vccio(c) w4 i/o(b) y19 pllout(0) ab12 i/o(d) p4 i/o(b) r19 i/o(e) u12 vccio(d) w5 i/o(b) y20 pllrst(1) ab13 i/o(d) p5 i/o(b) r20 i/o(e) u13 i/o(d) w6 i/o(c) y21 i/o(e) ab14 nc p6 vccio(b) r21 i/o(e) u14 vccio(d) w7 nc y22 i/o(e) ab15 i/o(d) p7 i/o(b) r22 i/o(e) u15 nc w8 nc aa1 tdo ab16 ioctrl(d) p8 vcc t1 i/o(b) u16 vccio(d) w9 nc aa2 pllout(1) ab17 i/o(d) p9 gnd t2 i/o(b) u17 vccio(e) w10 nc aa3 gnd ab18 i/o(d) p10 vcc t3 i/o(b) u18 i/o(e) w11 i/o(c) aa4 i/o(b) ab19 i/o(e) p11 gnd t4 i/o(b) u19 i/o(e) w12 nc aa5 i/o(c) ab20 gnd p12 vcc t5 i/o(b) u20 ioctrl(e) w13 i/o(d) aa6 i/o(c) ab21 vccpll(1) p13 vcc t6 vccio(b) u21 nc w14 nc aa7 nc ab22 i/o(e) p14 gnd t7 gnd u22 inref(e) w15 i/o(d) aa8 inref(c) p15 vded t8 i/o(c) v1 i/o(b) w16 nc aa9 nc table 27: 484 pbga pinout table (continued) ball function ball function ball function ball function ball function ball function
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 45 ql6325 - 208 pqfp pinout diagram eclipse ql6325-4pq208c
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 46 ql6325 - 208 pqfp pinout table table 28: 208 pqfp pinout table pin function pin function pin function pin function pin function 1 pllrst(3) 43 io(b) 85 io(d) 127 clk(5)/pllin(3) 169 ioctrl(g) 2 vccpll(3) 44 vccio(b) 86 vcc 128 clk(6) 170 inref(g) 3 gnd 45 io(b) 87 io(d) 129 vcc 171 ioctrl(g) 4 gnd 46 vcc 88 io(d) 130 clk(7) 172 io(g) 5 io(a) 47 io(b) 89 vcc 131 vcc 173 io(g) 6 io(a) 48 io(b) 90 io(d) 132 clk(8) 174 io(g) 7 io(a) 49 gnd 91 io(d) 133 tms 175 vcc 8 vccio(a) 50 tdo 92 ioctrl(d) 134 io(f) 176 io(g) 9 io(a) 51 pllout(1) 93 inref(d) 135 io(f) 177 vccio(g) 10 io(a) 52 gndpll(2) 94 ioctrl(d) 136 io(f) 178 gnd 11 ioctrl(a) 53 gnd 95 io(d) 137 gnd 179 io(g) 12 vcc 54 vccpll(2) 96 io(d) 138 vccio(f) 180 io(g) 13 inref(a) 55 pllrst(2) 97 io(d) 139 io(f) 181 io(g) 14 ioctrl(a) 56 vcc 98 vccio(d) 140 io(f) 182 vcc 15 io(a) 57 io(c) 99 io(d) 141 io(f) 183 tck 16 io(a) 58 gnd 100 io(d) 142 io(f) 184 vcc 17 io(a) 59 io(c) 101 gnd 143 io(f) 185 io(h) 18 io(a) 60 vccio(c) 102 pllout(0) 144 ioctrl(f) 186 io(h) 19 vccio(a) 61 io(c) 103 gnd 145 inref(f) 187 io(h) 20 io(a) 62 io(c) 104 gndpll(1) 146 vcc 188 gnd 21 gnd 63 io(c) 105 pllrst(1) 147 ioctrl(f) 189 vccio(h) 22 io(a) 64 io(c) 106 vccpll(1) 148 io(f) 190 io(h) 23 tdi 65 io(c) 107 io(e) 149 io(f) 191 io(h) 24 clk(0) 66 io(c) 108 gnd 150 vccio(f) 192 ioctrl(h) 25 clk(1) 67 ioctrl(c) 109 io(e) 151 io(f) 193 io(h) 26 vcc 68 inref(c) 110 io(e) 152 io(f) 194 inref(h) 27 clk(2)/pllin(2) 69 ioctrl(c) 111 vccio(e) 153 gnd 195 vcc 28 clk(3)/pllin(1) 70 io(c) 112 io(e) 154 io(f) 196 ioctrl(h) 29 vcc 71 io(c) 113 vcc 155 pllout(3) 197 io(h) 30 clk(4)/ dedclk/pllin(0) 72 vccio(c) 114 io(e) 156 gndpll(0) 198 io(h) 31 io(b) 73 io(c) 115 io(e) 157 gnd 199 io(h) 32 io(b) 74 io(c) 116 io(e) 158 vccpll(0) 200 io(h) 33 gnd 75 gnd 117 ioctrl(e) 159 pllrst(0) 201 io(h) 34 vccio(b) 76 vcc 118 inref(e) 160 gnd 202 io(h) 35 io(b) 77 io(c) 119 ioctrl(e) 161 io(g) 203 vccio(h) 36 io(b) 78 trstb 120 io(e) 162 vccio(g) 204 gnd 37 io(b) 79 vcc 121 io(e) 163 io(g) 205 io(h) 38 io(b) 80 io(d) 122 vccio(e) 164 io(g) 206 pllout(2) 39 ioctrl(b) 81 io(d) 123 gnd 165 vcc 207 gnd 40 inref(b) 82 io(d) 124 io(e) 166 io(g) 208 gndpll(3) 41 ioctrl(b) 83 gnd 125 io(e) 167 io(g) 42 io(b) 84 vccio(d) 126 io(e) 168 io(g)
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 47 ql6325 - 280 lfbga pinout diagram top bottom eclipse ql6325-4pt280c pin a1 corner
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 48 ql6325 - 280 lfbga pinout table table 29: 280 lfbga pinout table ball function ball function ball function ball function ball function ball function a1 pllout(3) c10 clk(5)/ pllin(3) e19 ioctrl(d) k16 i/o(c) r4 i/o(h) u13 i/o(b) a2 gndpll(0) c11 vccio(e) f1 inref(g) k17 i/o(d) r5 gnd u14 ioctrl(b) a3 i/o(f) c12 i/o(e) f2 ioctrl(g) k18 i/o(c) r6 gnd u15 vccio(b) a4 i/o(f) c13 i/o(e) f3 i/o(g) k19 trstb r7 vcc u16 i/o(b) a5 i/o(f) c14 i/o(e) f4 i/o(g) l1 i/o(h) r8 vcc u17 tdo a6 ioctrl(f) c15 vccio(e) f5 gnd l2 i/o(h) r9 gnd u18 pllrst(2) a7 i/o(f) c16 i/o(e) f15 vcc l3 vccio(h) r10 gnd u19 i/o(b) a8 i/o(f) c17 i/o(e) f16 ioctrl(d) l4 i/o(h) r11 vcc v1 pllout(2) a9 i/o(f) c18 i/o(e) f17 i/o(d) l5 vcc r12 vcc v2 gndpll(3) a10 clk(7) c19 i/o(e) f18 i/o(d) l15 gnd r13 vcc v3 gnd a11 i/o(e) d1 i/o(g) f19 i/o(d) l16 i/o(c) r14 vcc v4 i/o(a) a12 i/o(e) d2 i/o(g) g1 i/o(g) l17 vccio(c) r15 gnd v5 i/o(a) a13 i/o(e) d3 i/o(f) g2 i/o(g) l18 i/o(c) r16 i/o(c) v6 ioctrl(a) a14 ioctrl(e) d4 i/o(f) g3 ioctrl(g) l19 i/o(c) r17 vccio(c) v7 i/o(a) a15 i/o(e) d5 i/o(f) g4 i/o(g) m1 i/o(h) r18 i/o(c) v8 i/o(a) a16 i/o(e) d6 i/o(f) g5 vcc m2 i/o(h) r19 i/o(c) v9 i/o(a) a17 i/o(e) d7 i/o(f) g15 vcc m3 i/o(h) t1 i/o(h) v10 clk(1) a18 pllrst(1) d8 i/o(f) g16 i/o(d) m4 i/o(h) t2 i/o(h) v11 clk(4)/ dedclk/ pllin(0) a19 gnd d9 clk(8) g17 i/o(d) m5 vcc t3 i/o(a) v12 i/o(b) b1 pllrst(0) d10 i/o(e) g18 i/o(d) m15 vcc t4 i/o(a) v13 i/o(b) b2 gnd d11 i/o(e) g19 i/o(d) m16 inref(c) t5 i/o(a) v14 inref(b) b3 i/o(f) d12 i/o(e) h1 i/o(g) m17 i/o(c) t6 ioctrl(a) v15 i/o(b) b4 i/o(f) d13 inref(e) h2 i/o(g) m18 i/o(c) t7 i/o(a) v16 i/o(b) b5 i/o(f) d14 i/o(e) h3 i/o(g) m19 i/o(c) t8 i/o(a) v17 i/o(b) b6 inref(f) d15 i/o(e) h4 i/o(g) n1 ioctrl(h) t9 i/o(a) v18 gndpll(2) b7 i/o(f) d16 i/o(d) h5 vcc n2 i/o(h) t10 i/o(a) v19 gnd b8 i/o(f) d17 i/o(d) h15 vcc n3 i/o(h) t11 clk(3)/ pllin(1) w1 gnd b9 tms d18 i/o(d) h16 vcc n4 i/o(h) t12 i/o(b) w2 pllrst(3) b10 clk(6) d19 i/o(d) h17 i/o(d) n5 vcc t13 i/o(b) w3 i/o(a) b11 i/o(e) e1 i/o(g) h18 i/o(d) n15 vcc t14 i/o(b) w4 i/o(a) b12 i/o(e) e2 i/o(g) h19 i/o(d) n16 i/o(c) t15 i/o(b) w5 i/o(a) b13 ioctrl(e) e3 vccio(g) j1 i/o(g) n17 i/o(c) t16 i/o(b) w6 i/o(a) b14 i/o(e) e4 i/o(f) j2 i/o(g) n18 ioctrl(c) t17 vccpll(2) w7 i/o(a) b15 i/o(e) e5 gnd j3 vccio(g) n19 ioctrl(c) t18 i/o(b) w8 i/o(a) b16 i/o(e) e6 vcc j4 i/o(g) p1 i/o(h) t19 i/o(b) w9 tdi b17 vccpll(1) e7 vcc j5 gnd p2 i/o(h) u1 i/o(a) w10 clk(2)/ pllin(2) b18 gndpll(1) e8 vcc j15 vcc p3 ioctrl(h) u2 i/o(a) w11 i/o(b) b19 pllout(0) e9 vcc j16 i/o(c) p4 inref(h) u3 vccpll(3) w12 i/o(b) c1 i/o(f) e10 gnd j17 vccio(d) p5 vcc u4 i/o(a) w13 i/o(b) c2 vccpll(0) e11 gnd j18 i/o(d) p15 gnd u5 vccio(a) w14 ioctrl(b) c3 i/o(f) e12 vcc j19 i/o(d) p16 i/o(c) u6 inref(a) w15 i/o(b) c4 i/o(f) e13 vcc k1 vcc p17 i/o(c) u7 i/o(a) w16 i/o(b) c5 vccio(f) e14 gnd k2 tck p18 i/o(c) u8 i/o(a) w17 i/o(b) c6 ioctrl(f) e15 gnd k3 i/o(g) p19 i/o(c) u9 vccio(a) w18 i/o(b) c7 i/o(f) e16 i/o(d) k4 i/o(g) r1 i/o(h) u10 clk(0) w19 pllout(1) c8 i/o(f) e17 vccio(d) k5 gnd r2 i/o(h) u11 vccio(b) c9 vccio(f) e18 inref(d) k15 gnd r3 vccio(h) u12 i/o(b)
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 49 ql6325 - 484 pbga pinout diagram top bottom eclipse ql6325-4ps484c 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 a b c e d f g h k j l m n r p t u v y w 22 21 a b aa pin a1 corner pin a1
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 50 ql6325 - 484 pbga pinout table table 30: 484 pbga pinout table ball function ball function ball function ball function ball function ball function a1 i/o(a) c1 i/o(a) e1 ioctrl(a) g1 i/o(a) j1 i/o(a) l1 clk(4)/ dedclk/ pllin(0) a2 pllrst(3) c2 i/o(a) e2 i/o(a) g2 i/o(a) j2 i/o(a) l2 clk(0) a3 i/o(a) c3 vccpll(3) e3 i/o(a) g3 i/o(a) j3 i/o(a) l3 clk(2)/pllin(2) a4 i/o(a) c4 pllout(2) e4 i/o(a) g4 i/o(a) j4 i/o(a) l4 i/o(a) a5 i/o(a) c5 i/o(a) e5 i/o(a) g5 i/o(a) j5 i/o(a) l5 i/o(a) a6 i/o(h) c6 i/o(h) e6 i/o(h) g6 i/o(a) j6 i/o(a) l6 i/o(a) a7 i/o(h) c7 i/o(h) e7 nc g7 gnd j7 i/o(a) l7 gnd a8 ioctrl(h) c8 i/o(h) e8 i/o(h) g8 i/o(h) j8 vcc l8 gnd a9 i/o(h) c9 ioctrl(h) e9 i/o(h) g9 i/o(h) j9 gnd l9 gnd a10 nc c10 i/o(h) e10 i/o(h) g10 i/o(h) j10 vcc l10 gnd a11 nc c11 i/o(h) e11 vded2 g11 i/o(g) j11 vcc l11 gnd a12 tck c12 i/o(h) e12 i/o(g) g12 gnd j12 gnd l12 gnd a13 i/o(g) c13 i/o(g) e13 i/o(g) g13 i/o(g) j13 vcc l13 gnd a14 i/o(g) c14 i/o(g) e14 i/o(g) g14 i/o(g) j14 gnd l14 vcc a15 i/o(g) c15 i/o(g) e15 ioctrl(g) g15 i/o(g) j15 vcc l15 vcc a16 i/o(g) c16 i/o(g) e16 i/o(g) g16 gnd j16 i/o(f) l16 clk(6) a17 i/o(g) c17 i/o(g) e17 inref(g) g17 vccio(f) j17 vccio(f) l17 vccio(f) a18 i/o(g) c18 i/o(g) e18 i/o(g) g18 i/o(f) j18 i/o(f) l18 i/o(f) a19 i/o(f) c19 i/o(f) e19 i/o(f) g19 i/o(f) j19 i/o(f) l19 clk(8) a20 gnd c20 gndpll(0) e20 i/o(f) g20 i/o(f) j20 i/o(f) l20 i/o(f) a21 pllout(3) c21 i/o(f) e21 i/o(f) g21 inref(f) j21 i/o(f) l21 i/o(f) a22 i/o(f) c22 i/o(f) e22 i/o(f) g22 i/o(f) j22 i/o(f) l22 i/o(f) b1 i/o(a) d1 i/o(a) f1 i/o(a) h1 i/o(a) k1 tdi m1 i/o(b) b2 gnd d2 i/o(a) f2 inref(a) h2 i/o(a) k2 i/o(a) m2 i/o(b) b3 gndpll(3) d3 i/o(a) f3 i/o(a) h3 i/o(a) k3 i/o(a) m3 i/o(b) b4 gnd d4 i/o(a) f4 i/o(a) h4 i/o(a) k4 i/o(a) m4 clk(3)/pllin(1) b5 i/o(a) d5 i/o(a) f5 i/o(a) h5 ioctrl(a) k5 i/o(a) m5 i/o(b) b6 i/o(h) d6 i/o(h) f6 vccio(a) h6 vccio(a) k6 vccio(a) m6 vccio(b) b7 i/o(h) d7 i/o(h) f7 vccio(h) h7 i/o(h) k7 i/o(a) m7 clk(1) b8 inref(h) d8 i/o(h) f8 i/o(h) h8 gnd k8 vcc m8 vcc b9 i/o(h) d9 i/o(h) f9 vccio(h) h9 vcc k9 vcc m9 vcc b10 i/o(h) d10 i/o(h) f10 i/o(h) h10 vcc k10 gnd m10 gnd b11 i/o(h) d11 i/o(h) f11 vccio(h) h11 vded k11 gnd m11 gnd b12 nc d12 i/o(g) f12 vccio(g) h12 gnd k12 gnd m12 gnd b13 nc d13 i/o(g) f13 i/o(g) h13 vcc k13 gnd m13 gnd b14 nc d14 i/o(g) f14 vccio(g) h14 vcc k14 vcc m14 gnd b15 i/o(g) d15 ioctrl(g) f15 nc h15 gnd k15 vcc m15 gnd b16 i/o(g) d16 i/o(g) f16 vccio(g) h16 i/o(f) k16 i/o(f) m16 gnd b17 i/o(g) d17 i/o(g) f17 nc h17 i/o(f) k17 i/o(f) m17 i/o(e) b18 i/o(g) d18 i/o(f) f18 i/o(f) h18 i/o(f) k18 i/o(f) m18 i/o(e) b19 pllrst(0) d19 vccpll(0) f19 i/o(f) h19 i/o(f) k19 i/o(f) m19 i/o(e) b20 i/o(f) d20 i/o(f) f20 ioctrl(f) h20 i/o(f) k20 i/o(f) m20 clk(7) b21 i/o(f) d21 i/o(f) f21 i/o(f) h21 i/o(f) k21 i/o(f) m21 clk(5)/pllin(3) b22 i/o(f) d22 i/o(f) f22 ioctrl(f) h22 i/o(f) k22 i/o(f) m22 tms
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 51 n1 i/o(b) p16 i/o(e) t9 nc v2 i/o(b) w17 i/o(d) aa10 i/o(c) n2 i/o(b) p17 i/o(e) t10 trstb v3 i/o(b) w18 i/o(e) aa11 i/o(c) n3 i/o(b) p18 i/o(e) t11 gnd v4 i/o(b) w19 i/o(e) aa12 i/o(d) n4 i/o(b) p19 i/o(e) t12 nc v5 i/o(b) w20 i/o(e) aa13 i/o(d) n5 i/o(b) p20 i/o(e) t13 i/o(d) v6 i/o(c) w21 i/o(e) aa14 i/o(d) n6 i/o(b) p21 i/o(e) t14 nc v7 i/o(c) w22 i/o(e) aa15 i/o(d) n7 i/o(b) p22 i/o(e) t15 i/o(d) v8 i/o(c) y1 i/o(b) aa16 i/o(d) n8 vcc r1 i/o(b) t16 gnd v9 nc y2 i/o(b) aa17 i/o(d) n9 vcc r2 inref(b) t17 i/o(e) v10 i/o(c) y3 vccpll(2) aa18 i/o(d) n10 gnd r3 i/o(b) t18 i/o(e) v11 i/o(c) y4 i/o(c) aa19 i/o(e) n11 gnd r4 i/o(b) t19 i/o(e) v12 vded2 y5 i/o(c) aa20 gndpll(1) n12 gnd r5 i/o(b) t20 i/o(e) v13 nc y6 i/o(c) aa21 i/o(e) n13 gnd r6 i/o(b) t21 ioctrl(e) v14 i/o(d) y7 i/o(c) aa22 i/o(e) n14 vcc r7 i/o(b) t22 i/o(e) v15 i/o(d) y8 ioctrl(c) ab1 i/o(b) n15 vcc r8 gnd u1 ioctrl(b) v16 inref(d) y9 i/o(c) ab2 gndpll(2) n16 i/o(e) r9 vcc u2 i/o(b) v17 i/o(d) y10 i/o(c) ab3 pllrst(2) n17 vccio(e) r10 vcc u3 ioctrl(b) v18 i/o(e) y11 i/o(d) ab4 i/o(b) n18 i/o(e) r11 gnd u4 i/o(b) v19 i/o(e) y12 i/o(d) ab5 i/o(b) n19 i/o(e) r12 vded u5 i/o(b) v20 i/o(e) y13 i/o(d) ab6 i/o(c) n20 i/o(e) r13 vcc u6 i/o(c) v21 i/o(e) y14 i/o(d) ab7 i/o(c) n21 i/o(e) r14 vcc u7 vccio(c) v22 i/o(e) y15 ioctrl(d) ab8 ioctrl(c) n22 i/o(e) r15 gnd u8 nc w1 i/o(b) y16 i/o(d) ab9 i/o(c) p1 i/o(b) r16 i/o(d) u9 vccio(c) w2 i/o(b) y17 i/o(d) ab10 i/o(c) p2 i/o(b) r17 vccio(e) u10 i/o(c) w3 i/o(b) y18 i/o(e) ab11 i/o(c) p3 i/o(b) r18 i/o(e) u11 vccio(c) w4 i/o(b) y19 pllout(0) ab12 i/o(d) p4 i/o(b) r19 i/o(e) u12 vccio(d) w5 i/o(b) y20 pllrst(1) ab13 i/o(d) p5 i/o(b) r20 i/o(e) u13 i/o(d) w6 i/o(c) y21 i/o(e) ab14 i/o(d) p6 vccio(b) r21 i/o(e) u14 vccio(d) w7 nc y22 i/o(e) ab15 i/o(d) p7 i/o(b) r22 i/o(e) u15 nc w8 i/o(c) aa1 tdo ab16 ioctrl(d) p8 vcc t1 i/o(b) u16 vccio(d) w9 i/o(c) aa2 pllout(1) ab17 i/o(d) p9 gnd t2 i/o(b) u17 vccio(e) w10 i/o(c) aa3 gnd ab18 i/o(d) p10 vcc t3 i/o(b) u18 i/o(e) w11 i/o(c) aa4 i/o(b) ab19 i/o(e) p11 gnd t4 i/o(b) u19 i/o(e) w12 i/o(d) aa5 i/o(c) ab20 gnd p12 vcc t5 i/o(b) u20 ioctrl(e) w13 i/o(d) aa6 i/o(c) ab21 vccpll(1) p13 vcc t6 vccio(b) u21 i/o(e) w14 i/o(d) aa7 i/o(c) ab22 i/o(e) p14 gnd t7 gnd u22 inref(e) w15 i/o(d) aa8 inref(c) p15 vded t8 i/o(c) v1 i/o(b) w16 nc aa9 i/o(c) table 30: 484 pbga pinout table (continued) ball function ball function ball function ball function ball function ball function
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 52 ql6500 - 280 lfbga pinout diagram top bottom eclipse ql6500-4pt280c pin a1 corner
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 53 ql6500 - 280 lfbga pinout table table 31: 280 lfbga pinout table ball function ball function ball function ball function ball function ball function a1 pllout(3) c10 clk(5)/ pllin(3) e19 ioctrl(d) k16 i/o(c) r4 i/o(h) u13 i/o(b) a2 gndpll(0) c11 vccio(e) f1 inref(g) k17 i/o(d) r5 gnd u14 ioctrl(b) a3 i/o(f) c12 i/o(e) f2 ioctrl(g) k18 i/o(c) r6 gnd u15 vccio(b) a4 i/o(f) c13 i/o(e) f3 i/o(g) k19 trstb r7 vcc u16 i/o(b) a5 i/o(f) c14 i/o(e) f4 i/o(g) l1 i/o(h) r8 vcc u17 tdo a6 ioctrl(f) c15 vccio(e) f5 gnd l2 i/o(h) r9 gnd u18 pllrst(2) a7 i/o(f) c16 i/o(e) f15 vcc l3 vccio(h) r10 gnd u19 i/o(b) a8 i/o(f) c17 i/o(e) f16 ioctrl(d) l4 i/o(h) r11 vcc v1 pllout(2) a9 i/o(f) c18 i/o(e) f17 i/o(d) l5 vcc r12 vcc v2 gndpll(3) a10 clk(7) c19 i/o(e) f18 i/o(d) l15 gnd r13 vcc v3 gnd a11 i/o(e) d1 i/o(g) f19 i/o(d) l16 i/o(c) r14 vcc v4 i/o(a) a12 i/o(e) d2 i/o(g) g1 i/o(g) l17 vccio(c) r15 gnd v5 i/o(a) a13 i/o(e) d3 i/o(f) g2 i/o(g) l18 i/o(c) r16 i/o(c) v6 ioctrl(a) a14 ioctrl(e) d4 i/o(f) g3 ioctrl(g) l19 i/o(c) r17 vccio(c) v7 i/o(a) a15 i/o(e) d5 i/o(f) g4 i/o(g) m1 i/o(h) r18 i/o(c) v8 i/o(a) a16 i/o(e) d6 i/o(f) g5 vcc m2 i/o(h) r19 i/o(c) v9 i/o(a) a17 i/o(e) d7 i/o(f) g15 vcc m3 i/o(h) t1 i/o(h) v10 clk(1) a18 pllrst(1) d8 i/o(f) g16 i/o(d) m4 i/o(h) t2 i/o(h) v11 clk(4)/ dedclk/ pllin(0) a19 gnd d9 clk(8) g17 i/o(d) m5 vcc t3 i/o(a) v12 i/o(b) b1 pllrst(0) d10 i/o(e) g18 i/o(d) m15 vcc t4 i/o(a) v13 i/o(b) b2 gnd d11 i/o(e) g19 i/o(d) m16 inref(c) t5 i/o(a) v14 inref(b) b3 i/o(f) d12 i/o(e) h1 i/o(g) m17 i/o(c) t6 ioctrl(a) v15 i/o(b) b4 i/o(f) d13 inref(e) h2 i/o(g) m18 i/o(c) t7 i/o(a) v16 i/o(b) b5 i/o(f) d14 i/o(e) h3 i/o(g) m19 i/o(c) t8 i/o(a) v17 i/o(b) b6 inref(f) d15 i/o(e) h4 i/o(g) n1 ioctrl(h) t9 i/o(a) v18 gndpll(2) b7 i/o(f) d16 i/o(d) h5 vcc n2 i/o(h) t10 i/o(a) v19 gnd b8 i/o(f) d17 i/o(d) h15 vcc n3 i/o(h) t11 clk(3)/ pllin(1) w1 gnd b9 tms d18 i/o(d) h16 vcc n4 i/o(h) t12 i/o(b) w2 pllrst(3) b10 clk(6) d19 i/o(d) h17 i/o(d) n5 vcc t13 i/o(b) w3 i/o(a) b11 i/o(e) e1 i/o(g) h18 i/o(d) n15 vcc t14 i/o(b) w4 i/o(a) b12 i/o(e) e2 i/o(g) h19 i/o(d) n16 i/o(c) t15 i/o(b) w5 i/o(a) b13 ioctrl(e) e3 vccio(g) j1 i/o(g) n17 i/o(c) t16 i/o(b) w6 i/o(a) b14 i/o(e) e4 i/o(f) j2 i/o(g) n18 ioctrl(c) t17 vccpll(2) w7 i/o(a) b15 i/o(e) e5 gnd j3 vccio(g) n19 ioctrl(c) t18 i/o(b) w8 i/o(a) b16 i/o(e) e6 vcc j4 i/o(g) p1 i/o(h) t19 i/o(b) w9 tdi b17 vccpll(1) e7 vcc j5 gnd p2 i/o(h) u1 i/o(a) w10 clk(2)/ pllin(2) b18 gndpll(1) e8 vcc j15 vcc p3 ioctrl(h) u2 i/o(a) w11 i/o(b) b19 pllout(0) e9 vcc j16 i/o(c) p4 inref(h) u3 vccpll(3) w12 i/o(b) c1 i/o(f) e10 gnd j17 vccio(d) p5 vcc u4 i/o(a) w13 i/o(b) c2 vccpll(0) e11 gnd j18 i/o(d) p15 gnd u5 vccio(a) w14 ioctrl(b) c3 i/o(f) e12 vcc j19 i/o(d) p16 i/o(c) u6 inref(a) w15 i/o(b) c4 i/o(f) e13 vcc k1 vcc p17 i/o(c) u7 i/o(a) w16 i/o(b) c5 vccio(f) e14 gnd k2 tck p18 i/o(c) u8 i/o(a) w17 i/o(b) c6 ioctrl(f) e15 gnd k3 i/o(g) p19 i/o(c) u9 vccio(a) w18 i/o(b) c7 i/o(f) e16 i/o(d) k4 i/o(g) r1 i/o(h) u10 clk(0) w19 pllout(1) c8 i/o(f) e17 vccio(d) k5 gnd r2 i/o(h) u11 vccio(b) c9 vccio(f) e18 inref(d) k15 gnd r3 vccio(h) u12 i/o(b)
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 54 ql6500 - 484 pbga pinout diagram top bottom eclipse ql6500-4ps484c 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 a b c e d f g h k j l m n r p t u v y w 22 21 a b aa pin a1 corner pin a1
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 55 ql6500 - 484 pbga pinout table table 32: 484 pbga pinout table ball function ball function ball function ball function ball function ball function a1 i/o(a) c1 i/o(a) e1 ioctrl(a) g1 i/o(a) j1 i/o(a) l1 clk(4)/ dedclk/ pllin(0) a2 pllrst(3) c2 i/o(a) e2 i/o(a) g2 i/o(a) j2 i/o(a) l2 clk(0) a3 i/o(a) c3 vccpll(3) e3 i/o(a) g3 i/o(a) j3 i/o(a) l3 clk(2)/pllin(2) a4 i/o(a) c4 pllout(2) e4 i/o(a) g4 i/o(a) j4 i/o(a) l4 i/o(a) a5 i/o(a) c5 i/o(a) e5 i/o(a) g5 i/o(a) j5 i/o(a) l5 i/o(a) a6 i/o(h) c6 i/o(h) e6 i/o(h) g6 i/o(a) j6 i/o(a) l6 i/o(a) a7 i/o(h) c7 i/o(h) e7 i/o(h) g7 gnd j7 i/o(a) l7 gnd a8 ioctrl(h) c8 i/o(h) e8 i/o(h) g8 i/o(h) j8 vcc l8 gnd a9 i/o(h) c9 ioctrl(h) e9 i/o(h) g9 i/o(h) j9 gnd l9 gnd a10 i/o(h) c10 i/o(h) e10 i/o(h) g10 i/o(h) j10 vcc l10 gnd a11 i/o(h) c11 i/o(h) e11 vded2 g11 i/o(g) j11 vcc l11 gnd a12 tck c12 i/o(h) e12 i/o(g) g12 gnd j12 gnd l12 gnd a13 i/o(g) c13 i/o(g) e13 i/o(g) g13 i/o(g) j13 vcc l13 gnd a14 i/o(g) c14 i/o(g) e14 i/o(g) g14 i/o(g) j14 gnd l14 vcc a15 i/o(g) c15 i/o(g) e15 ioctrl(g) g15 i/o(g) j15 vcc l15 vcc a16 i/o(g) c16 i/o(g) e16 i/o(g) g16 gnd j16 i/o(f) l16 clk(6) a17 i/o(g) c17 i/o(g) e17 inref(g) g17 vccio(f) j17 vccio(f) l17 vccio(f) a18 i/o(g) c18 i/o(g) e18 i/o(g) g18 i/o(f) j18 i/o(f) l18 i/o(f) a19 i/o(f) c19 i/o(f) e19 i/o(f) g19 i/o(f) j19 i/o(f) l19 clk(8) a20 gnd c20 gndpll(0) e20 i/o(f) g20 i/o(f) j20 i/o(f) l20 i/o(f) a21 pllout(3) c21 i/o(f) e21 i/o(f) g21 inref(f) j21 i/o(f) l21 i/o(f) a22 i/o(f) c22 i/o(f) e22 i/o(f) g22 i/o(f) j22 i/o(f) l22 i/o(f) b1 i/o(a) d1 i/o(a) f1 i/o(a) h1 i/o(a) k1 tdi m1 i/o(b) b2 gnd d2 i/o(a) f2 inref(a) h2 i/o(a) k2 i/o(a) m2 i/o(b) b3 gndpll(3) d3 i/o(a) f3 i/o(a) h3 i/o(a) k3 i/o(a) m3 i/o(b) b4 gnd d4 i/o(a) f4 i/o(a) h4 i/o(a) k4 i/o(a) m4 clk(3)/pllin(1) b5 i/o(a) d5 i/o(a) f5 i/o(a) h5 ioctrl(a) k5 i/o(a) m5 i/o(b) b6 i/o(h) d6 i/o(h) f6 vccio(a) h6 vccio(a) k6 vccio(a) m6 vccio(b) b7 i/o(h) d7 i/o(h) f7 vccio(h) h7 i/o(h) k7 i/o(a) m7 clk(1) b8 inref(h) d8 i/o(h) f8 i/o(h) h8 gnd k8 vcc m8 vcc b9 i/o(h) d9 i/o(h) f9 vccio(h) h9 vcc k9 vcc m9 vcc b10 i/o(h) d10 i/o(h) f10 i/o(h) h10 vcc k10 gnd m10 gnd b11 i/o(h) d11 i/o(h) f11 vccio(h) h11 vded k11 gnd m11 gnd b12 i/o(g) d12 i/o(g) f12 vccio(g) h12 gnd k12 gnd m12 gnd b13 i/o(g) d13 i/o(g) f13 i/o(g) h13 vcc k13 gnd m13 gnd b14 i/o(g) d14 i/o(g) f14 vccio(g) h14 vcc k14 vcc m14 gnd b15 i/o(g) d15 ioctrl(g) f15 i/o(g) h15 gnd k15 vcc m15 gnd b16 i/o(g) d16 i/o(g) f16 vccio(g) h16 i/o(f) k16 i/o(f) m16 gnd b17 i/o(g) d17 i/o(g) f17 i/o(g) h17 i/o(f) k17 i/o(f) m17 i/o(e) b18 i/o(g) d18 i/o(f) f18 i/o(f) h18 i/o(f) k18 i/o(f) m18 i/o(e) b19 pllrst(0) d19 vccpll(0) f19 i/o(f) h19 i/o(f) k19 i/o(f) m19 i/o(e) b20 i/o(f) d20 i/o(f) f20 ioctrl(f) h20 i/o(f) k20 i/o(f) m20 clk(7) b21 i/o(f) d21 i/o(f) f21 i/o(f) h21 i/o(f) k21 i/o(f) m21 clk(5)/pllin(3) b22 i/o(f) d22 i/o(f) f22 ioctrl(f) h22 i/o(f) k22 i/o(f) m22 tms
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 56 n1 i/o(b) p16 i/o(e) t9 i/o(c) v2 i/o(b) w17 i/o(d) aa10 i/o(c) n2 i/o(b) p17 i/o(e) t10 trstb v3 i/o(b) w18 i/o(e) aa11 i/o(c) n3 i/o(b) p18 i/o(e) t11 gnd v4 i/o(b) w19 i/o(e) aa12 i/o(d) n4 i/o(b) p19 i/o(e) t12 i/o(c) v5 i/o(b) w20 i/o(e) aa13 i/o(d) n5 i/o(b) p20 i/o(e) t13 i/o(d) v6 i/o(c) w21 i/o(e) aa14 i/o(d) n6 i/o(b) p21 i/o(e) t14 i/o(d) v7 i/o(c) w22 i/o(e) aa15 i/o(d) n7 i/o(b) p22 i/o(e) t15 i/o(d) v8 i/o(c) y1 i/o(b) aa16 i/o(d) n8 vcc r1 i/o(b) t16 gnd v9 i/o(c) y2 i/o(b) aa17 i/o(d) n9 vcc r2 inref(b) t17 i/o(e) v10 i/o(c) y3 vccpll(2) aa18 i/o(d) n10 gnd r3 i/o(b) t18 i/o(e) v11 i/o(c) y4 i/o(c) aa19 i/o(e) n11 gnd r4 i/o(b) t19 i/o(e) v12 vded2 y5 i/o(c) aa20 gndpll(1) n12 gnd r5 i/o(b) t20 i/o(e) v13 i/o(d) y6 i/o(c) aa21 i/o(e) n13 gnd r6 i/o(b) t21 ioctrl(e) v14 i/o(d) y7 i/o(c) aa22 i/o(e) n14 vcc r7 i/o(b) t22 i/o(e) v15 i/o(d) y8 ioctrl(c) ab1 i/o(b) n15 vcc r8 gnd u1 ioctrl(b) v16 inref(d) y9 i/o(c) ab2 gndpll(2) n16 i/o(e) r9 vcc u2 i/o(b) v17 i/o(d) y10 i/o(c) ab3 pllrst(2) n17 vccio(e) r10 vcc u3 ioctrl(b) v18 i/o(e) y11 i/o(d) ab4 i/o(b) n18 i/o(e) r11 gnd u4 i/o(b) v19 i/o(e) y12 i/o(d) ab5 i/o(b) n19 i/o(e) r12 vded u5 i/o(b) v20 i/o(e) y13 i/o(d) ab6 i/o(c) n20 i/o(e) r13 vcc u6 i/o(c) v21 i/o(e) y14 i/o(d) ab7 i/o(c) n21 i/o(e) r14 vcc u7 vccio(c) v22 i/o(e) y15 ioctrl(d) ab8 ioctrl(c) n22 i/o(e) r15 gnd u8 i/o(c) w1 i/o(b) y16 i/o(d) ab9 i/o(c) p1 i/o(b) r16 i/o(d) u9 vccio(c) w2 i/o(b) y17 i/o(d) ab10 i/o(c) p2 i/o(b) r17 vccio(e) u10 i/o(c) w3 i/o(b) y18 i/o(e) ab11 i/o(c) p3 i/o(b) r18 i/o(e) u11 vccio(c) w4 i/o(b) y19 pllout(0) ab12 i/o(d) p4 i/o(b) r19 i/o(e) u12 vccio(d) w5 i/o(b) y20 pllrst(1) ab13 i/o(d) p5 i/o(b) r20 i/o(e) u13 i/o(d) w6 i/o(c) y21 i/o(e) ab14 i/o(d) p6 vccio(b) r21 i/o(e) u14 vccio(d) w7 i/o(c) y22 i/o(e) ab15 i/o(d) p7 i/o(b) r22 i/o(e) u15 i/o(d) w8 i/o(c) aa1 tdo ab16 ioctrl(d) p8 vcc t1 i/o(b) u16 vccio(d) w9 i/o(c) aa2 pllout(1) ab17 i/o(d) p9 gnd t2 i/o(b) u17 vccio(e) w10 i/o(c) aa3 gnd ab18 i/o(d) p10 vcc t3 i/o(b) u18 i/o(e) w11 i/o(c) aa4 i/o(b) ab19 i/o(e) p11 gnd t4 i/o(b) u19 i/o(e) w12 i/o(d) aa5 i/o(c) ab20 gnd p12 vcc t5 i/o(b) u20 ioctrl(e) w13 i/o(d) aa6 i/o(c) ab21 vccpll(1) p13 vcc t6 vccio(b) u21 i/o(e) w14 i/o(d) aa7 i/o(c) ab22 i/o(e) p14 gnd t7 gnd u22 inref(e) w15 i/o(d) aa8 inref(c) p15 vded t8 i/o(c) v1 i/o(b) w16 i/o(d) aa9 i/o(c) table 32: 484 pbga pinout table (continued) ball function ball function ball function ball function ball function ball function
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 57 ql6500 - 516 pbga pinout diagram top bottom eclipse ql6500-4pb516c pin a1 corner
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 58 ql6500 - 516 pbga pinout table table 33: 516 pbga pinout table ball function ball function ball function ball function ball function ball function a1 gnd c1 i/o(f) e1 i/o(g) g1 i/o(g) l5 vcc p3 i/o(h) a2 i/o(f) c2 i/o(f) e2 i/o(g) g2 inref(g) l6 vcc p4 vcc a3 i/o(f) c3 i/o(f) e3 i/o(g) g3 i/o(g) l11 gnd p5 i/o(h) a4 i/o(f) c4 pllout(3) e4 vccpll(0) g4 i/o(g) l12 gnd p6 vccio(h) a5 i/o(f) c5 i/o(f) e5 i/o(f) g5 i/o(g) l13 gnd p11 gnd a6 i/o(f) c6 i/o(f) e6 i/o(f) g6 vccio(g) l14 gnd p12 gnd a7 ioctrl(f) c7 i/o(f) e7 i/o(f) g21 vccio(d) l15 gnd p13 gnd a8 i/o(f) c8 inref(f) e8 vcc g22 i/o(d) l16 gnd p14 gnd a9 i/o(f) c9 i/o(f) e9 i/o(f) g23 i/o(d) l21 vcc p15 gnd a10 i/o(f) c10 i/o(f) e10 i/o(f) g24 i/o(d) l22 i/o(d) p16 gnd a11 i/o(f) c11 i/o(f) e11 i/o(f) g25 i/o(d) l23 i/o(d) p21 vccio(c) a12 i/o(f) c12 i/o(f) e12 vcc g26 inref(d) l24 i/o(d) p22 i/o(c) a13 i/o(e) c13 clk(7) e13 i/o(f) h1 i/o(g) l25 i/o(d) p23 vcc a14 i/o(e) c14 i/o(e) e14 i/o(f) h2 i/o(g) l26 i/o(d) p24 i/o(c) a15 i/o(e) c15 i/o(e) e15 i/o(e) h3 ioctrl(g) m1 i/o(g) p25 i/o(c) a16 i/o(e) c16 i/o(e) e16 vcc h4 i/o(g) m2 i/o(g) p26 trstb a17 i/o(e) c17 i/o(e) e17 clk(6) h5 i/o(g) m3 i/o(g) r1 i/o(h) a18 ioctrl(e) c18 i/o(e) e18 i/o(e) h6 vcc m4 i/o(g) r2 i/o(h) a19 ioctrl(e) c19 i/o(e) e19 i/o(e) h21 vcc m5 i/o(g) r3 i/o(h) a20 i/o(e) c20 i/o(e) e20 i/o(e) h22 vcc m6 vccio(g) r4 i/o(h) a21 i/o(e) c21 i/o(e) e21 i/o(e) h23 i/o(d) m11 gnd r5 vcc a22 i/o(e) c22 i/o(e) e22 i/o(e) h24 ioctrl(d) m12 gnd r6 vcc a23 i/o(e) c23 i/o(e) e23 gndpll(1) h25 ioctrl(d) m13 gnd r11 gnd a24 i/o(e) c24 i/o(e) e24 i/o(e) h26 i/o(d) m14 gnd r12 gnd a25 pllrst(1) c25 i/o(e) e25 i/o(d) j1 i/o(g) m15 gnd r13 gnd a26 gnd c26 i/o(e) e26 i/o(d) j2 i/o(g) m16 gnd r14 gnd b1 i/o(f) d1 i/o(g) f1 ioctrl(g) j3 i/o(g) m21 vccio(d) r15 gnd b2 pllrst(0) d2 i/o(g) f2 i/o(g) j4 i/o(g) m22 vcc r16 gnd b3 i/o(f) d3 i/o(f) f3 i/o(g) j5 i/o(g) m23 i/o(d) r21 vcc b4 i/o(f) d4 i/o(f) f4 i/o(g) j6 vccio(g) m24 i/o(d) r22 i/o(c) b5 i/o(f) d5 gndpll(0) f5 i/o(f) j21 vccio(d) m25 i/o(d) r23 i/o(c) b6 i/o(f) d6 i/o(f) f6 gnd j22 i/o(d) m26 i/o(d) r24 i/o(c) b7 ioctrl(f) d7 i/o(f) f7 vccio(f) j23 i/o(d) n1 tck r25 i/o(c) b8 i/o(f) d8 i/o(f) f8 vcc j24 i/o(d) n2 i/o(h) r26 i/o(c) b9 i/o(f) d9 i/o(f) f9 vccio(f) j25 i/o(d) n3 i/o(g) t1 i/o(h) b10 i/o(f) d10 i/o(f) f10 gnd j26 i/o(d) n4 i/o(g) t2 i/o(h) b11 i/o(f) d11 i/o(f) f11 vcc k1 i/o(g) n5 i/o(g) t3 i/o(h) b12 i/o(f) d12 i/o(f) f12 vccio(f) k2 i/o(g) n6 gnd t4 i/o(h) b13 clk(5)/ pllin(3) d13 tms f13 gnd k3 i/o(g) n11 gnd t5 i/o(h) b14 i/o(e) d14 i/o(e) f14 vccio(e) k4 i/o(g) n12 gnd t6 vcc b15 i/o(e) d15 i/o(e) f15 vcc k5 i/o(g) n13 gnd t11 gnd b16 i/o(e) d16 i/o(f) f16 vcc k6 gnd n14 gnd t12 gnd b17 i/o(e) d17 i/o(e) f17 gnd k21 gnd n15 gnd t13 gnd b18 inref(e) d18 i/o(f) f18 vccio(e) k22 i/o(d) n16 gnd t14 gnd b19 i/o(e) d19 clk(8) f19 vcc k23 i/o(d) n21 gnd t15 gnd b20 i/o(e) d20 i/o(e) f20 vccio(e) k24 i/o(d) n22 i/o(d) t16 gnd b21 i/o(e) d21 i/o(e) f21 gnd k25 i/o(d) n23 i/o(d) t21 vcc b22 i/o(e) d22 i/o(e) f22 i/o(e) k26 i/o(d) n24 i/o(d) t22 vcc b23 i/o(e) d23 vccpll(1) f23 i/o(d) l1 i/o(g) n25 i/o(d) t23 i/o(c) b24 i/o(e) d24 i/o(e) f24 i/o(d) l2 i/o(g) n26 i/o(d) t24 i/o(c) b25 i/o(e) d25 i/o(e) f25 i/o(d) l3 i/o(g) p1 i/o(h) t25 i/o(c) b26 pllout(0) d26 i/o(d) f26 i/o(d) l4 i/o(g) p2 i/o(h) t26 i/o(c)
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 59 u1 i/o(h) w25 inref(c) aa21 gnd ac3 i/o(a) ad11 i/o(a) ae19 i/o(b) u2 i/o(h) w26 i/o(c) aa22 vccpll(2) ac4 i/o(a) ad12 tdi ae20 i/o(b) u3 i/o(h) y1 i/o(h) aa23 i/o(c) ac5 i/o(a) ad13 clk(4) dedclk/ pllin(0) ae21 i/o(b) u4 i/o(h) y2 i/o(h) aa24 i/o(c) ac6 i/o(a) ad14 i/o(a) ae22 i/o(b) u5 i/o(h) y3 i/o(h) aa25 i/o(c) ac7 i/o(a) ad15 i/o(b) ae23 i/o(b) u6 gnd y4 i/o(h) aa26 i/o(c) ac8 i/o(a) ad16 i/o(b) ae24 i/o(b) u21 gnd y5 i/o(h) ab1 i/o(h) ac9 i/o(a) ad17 i/o(b) ae25 pllrst(2) u22 i/o(c) y6 vccio(h) ab2 i/o(h) ac10 i/o(a) ad18 inref(b) ae26 i/o(b) u23 i/o(c) y21 vccio(c) ab3 i/o(a) ac11 i/o(a) ad19 i/o(b) af1 i/o(a) u24 i/o(c) y22 i/o(c) ab4 gndpll(3) ac12 i/o(a) ad20 i/o(b) af2 i/o(a) u25 i/o(c) y23 i/o(c) ab5 vccpll(3) ac13 i/o(a) ad21 i/o(b) af3 i/o(a) u26 i/o(c) y24 i/o(c) ab6 i/o(a) ac14 clk(1) ad22 i/o(b) af4 i/o(a) v1 i/o(h) y25 i/o(c) ab7 i/o(a) ac15 i/o(b) ad23 i/o(b) af5 i/o(a) v2 ioctrl(h) y26 ioctrl(c) ab8 i/o(a) ac16 i/o(b) ad24 gnd af6 ioctrl(a) v3 ioctrl(h) aa1 i/o(h) ab9 i/o(a) ac17 i/o(b) ad25 i/o(b) af7 i/o(a) v4 i/o(h) aa2 i/o(h) ab10 i/o(a) ac18 i/o(b) ad26 i/o(b) af8 i/o(a) v5 i/o(h) aa3 i/o(h) ab11 vcc ac19 i/o(b) ae1 gnd af9 i/o(a) v6 vccio(h) aa4 i/o(a) ab12 i/o(a) ac20 i/o(b) ae2 gnd af10 i/o(a) v21 vccio(c) aa5 i/o(a) ab13 i/o(a) ac21 i/o(b) ae3 i/o(a) af11 i/o(a) v22 i/o(c) aa6 gnd ab14 clk(3)/ pllin(1) ac22 tdo ae4 i/o(a) af12 clk(2)/ pllin(2) v23 i/o(c) aa7 vccio(a) ab15 vcc ac23 pllout(1) ae5 i/o(a) af13 i/o(b) v24 ioctrl(c) aa8 vcc ab16 i/o(b) ac24 i/o(b) ae6 i/o(a) af14 i/o(b) v25 i/o(c) aa9 vccio(a) ab17 i/o(b) ac25 i/o(b) ae7 inref(a) af15 i/o(b) v26 i/o(c) aa10 gnd ab18 i/o(b) ac26 i/o(c) ae8 i/o(a) af16 i/o(b) w1 inref(h) aa11 vcc ab19 vcc ad1 i/o(a) ae9 i/o(a) af17 i/o(b) w2 i/o(h) aa12 vccio(a) ab20 i/o(b) ad2 pllout(2) ae10 i/o(a) af18 i/o(b) w3 i/o(h) aa13 gnd ab21 i/o(b) ad3 pllrst(3) ae11 i/o(a) af19 ioctrl(b) w4 i/o(h) aa14 vccio(b) ab22 gndpll(2) ad4 i/o(a) ae12 clk(0) af20 ioctrl(b) w5 vcc aa15 vcc ab23 i/o(b) ad5 i/o(a) ae13 i/o(b) af21 i/o(b) w6 vcc aa16 vcc ab24 i/o(c) ad6 i/o(a) ae14 i/o(b) af22 i/o(b) w21 vcc aa17 gnd ab25 i/o(c) ad7 i/o(a) ae15 i/o(b) af23 i/o(b) w22 i/o(c) aa18 vccio(b) ab26 i/o(c) ad8 ioctrl(a) ae16 i/o(b) af24 i/o(b) w23 i/o(c) aa19 vcc ac1 i/o(a) ad9 i/o(a) ae17 i/o(b) af25 i/o(b) w24 i/o(c) aa20 vccio(b) ac2 i/o(a) ad10 i/o(a) ae18 i/o(b) af26 i/o(b) table 33: 516 pbga pinout table (continued) ball function ball function ball function ball function ball function ball function
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 60 ql6600 - 280 lfbga pinout diagram top bottom eclipse ql6600-4pt280c pin a1 corner
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 61 ql6600 - 280 lfbga pinout table table 34: 280 lfbga pinout table ball function ball function ball function ball function ball function ball function a1 pllout(3) c10 clk(5)/ pllin(3) e19 ioctrl(d) k16 i/o(c) r4 i/o(h) u13 i/o(b) a2 gndpll(0) c11 vccio(e) f1 inref(g) k17 i/o(d) r5 gnd u14 ioctrl(b) a3 i/o(f) c12 i/o(e) f2 ioctrl(g) k18 i/o(c) r6 gnd u15 vccio(b) a4 i/o(f) c13 i/o(e) f3 i/o(g) k19 trstb r7 vcc u16 i/o(b) a5 i/o(f) c14 i/o(e) f4 i/o(g) l1 i/o(h) r8 vcc u17 tdo a6 ioctrl(f) c15 vccio(e) f5 gnd l2 i/o(h) r9 gnd u18 pllrst(2) a7 i/o(f) c16 i/o(e) f15 vcc l3 vccio(h) r10 gnd u19 i/o(b) a8 i/o(f) c17 i/o(e) f16 ioctrl(d) l4 i/o(h) r11 vcc v1 pllout(2) a9 i/o(f) c18 i/o(e) f17 i/o(d) l5 vcc r12 vcc v2 gndpll(3) a10 clk(7) c19 i/o(e) f18 i/o(d) l15 gnd r13 vcc v3 gnd a11 i/o(e) d1 i/o(g) f19 i/o(d) l16 i/o(c) r14 vcc v4 i/o(a) a12 i/o(e) d2 i/o(g) g1 i/o(g) l17 vccio(c) r15 gnd v5 i/o(a) a13 i/o(e) d3 i/o(f) g2 i/o(g) l18 i/o(c) r16 i/o(c) v6 ioctrl(a) a14 ioctrl(e) d4 i/o(f) g3 ioctrl(g) l19 i/o(c) r17 vccio(c) v7 i/o(a) a15 i/o(e) d5 i/o(f) g4 i/o(g) m1 i/o(h) r18 i/o(c) v8 i/o(a) a16 i/o(e) d6 i/o(f) g5 vcc m2 i/o(h) r19 i/o(c) v9 i/o(a) a17 i/o(e) d7 i/o(f) g15 vcc m3 i/o(h) t1 i/o(h) v10 clk(1) a18 pllrst(1) d8 i/o(f) g16 i/o(d) m4 i/o(h) t2 i/o(h) v11 clk(4)/ dedclk/ pllin(0) a19 gnd d9 clk(8) g17 i/o(d) m5 vcc t3 i/o(a) v12 i/o(b) b1 pllrst(0) d10 i/o(e) g18 i/o(d) m15 vcc t4 i/o(a) v13 i/o(b) b2 gnd d11 i/o(e) g19 i/o(d) m16 inref(c) t5 i/o(a) v14 inref(b) b3 i/o(f) d12 i/o(e) h1 i/o(g) m17 i/o(c) t6 ioctrl(a) v15 i/o(b) b4 i/o(f) d13 inref(e) h2 i/o(g) m18 i/o(c) t7 i/o(a) v16 i/o(b) b5 i/o(f) d14 i/o(e) h3 i/o(g) m19 i/o(c) t8 i/o(a) v17 i/o(b) b6 inref(f) d15 i/o(e) h4 i/o(g) n1 ioctrl(h) t9 i/o(a) v18 gndpll(2) b7 i/o(f) d16 i/o(d) h5 vcc n2 i/o(h) t10 i/o(a) v19 gnd b8 i/o(f) d17 i/o(d) h15 vcc n3 i/o(h) t11 clk(3)/ pllin(1) w1 gnd b9 tms d18 i/o(d) h16 vcc n4 i/o(h) t12 i/o(b) w2 pllrst(3) b10 clk(6) d19 i/o(d) h17 i/o(d) n5 vcc t13 i/o(b) w3 i/o(a) b11 i/o(e) e1 i/o(g) h18 i/o(d) n15 vcc t14 i/o(b) w4 i/o(a) b12 i/o(e) e2 i/o(g) h19 i/o(d) n16 i/o(c) t15 i/o(b) w5 i/o(a) b13 ioctrl(e) e3 vccio(g) j1 i/o(g) n17 i/o(c) t16 i/o(b) w6 i/o(a) b14 i/o(e) e4 i/o(f) j2 i/o(g) n18 ioctrl(c) t17 vccpll(2) w7 i/o(a) b15 i/o(e) e5 gnd j3 vccio(g) n19 ioctrl(c) t18 i/o(b) w8 i/o(a) b16 i/o(e) e6 vcc j4 i/o(g) p1 i/o(h) t19 i/o(b) w9 tdi b17 vccpll(1) e7 vcc j5 gnd p2 i/o(h) u1 i/o(a) w10 clk(2)/ pllin(2) b18 gndpll(1) e8 vcc j15 vcc p3 ioctrl(h) u2 i/o(a) w11 i/o(b) b19 pllout(0) e9 vcc j16 i/o(c) p4 inref(h) u3 vccpll(3) w12 i/o(b) c1 i/o(f) e10 gnd j17 vccio(d) p5 vcc u4 i/o(a) w13 i/o(b) c2 vccpll(0) e11 gnd j18 i/o(d) p15 gnd u5 vccio(a) w14 ioctrl(b) c3 i/o(f) e12 vcc j19 i/o(d) p16 i/o(c) u6 inref(a) w15 i/o(b) c4 i/o(f) e13 vcc k1 vcc p17 i/o(c) u7 i/o(a) w16 i/o(b) c5 vccio(f) e14 gnd k2 tck p18 i/o(c) u8 i/o(a) w17 i/o(b) c6 ioctrl(f) e15 gnd k3 i/o(g) p19 i/o(c) u9 vccio(a) w18 i/o(b) c7 i/o(f) e16 i/o(d) k4 i/o(g) r1 i/o(h) u10 clk(0) w19 pllout(1) c8 i/o(f) e17 vccio(d) k5 gnd r2 i/o(h) u11 vccio(b) c9 vccio(f) e18 inref(d) k15 gnd r3 vccio(h) u12 i/o(b)
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 62 ql6600 - 484 pbga pinout diagram top bottom eclipse ql6600-4ps484c 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 a b c e d f g h k j l m n r p t u v y w 22 21 a b aa pin a1 corner pin a1
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 63 ql6600 - 484 pbga pinout table table 35: 484 pbga pinout table ball function ball function ball function ball function ball function ball function a1 i/o(a) c1 i/o(a) e1 ioctrl(a) g1 i/o(a) j1 i/o(a) l1 clk(4)/ dedclk/ pllin(0) a2 pllrst(3) c2 i/o(a) e2 i/o(a) g2 i/o(a) j2 i/o(a) l2 clk(0) a3 i/o(a) c3 vccpll(3) e3 i/o(a) g3 i/o(a) j3 i/o(a) l3 clk(2)/pllin(2) a4 i/o(a) c4 pllout(2) e4 i/o(a) g4 i/o(a) j4 i/o(a) l4 i/o(a) a5 i/o(a) c5 i/o(a) e5 i/o(a) g5 i/o(a) j5 i/o(a) l5 i/o(a) a6 i/o(h) c6 i/o(h) e6 i/o(h) g6 i/o(a) j6 i/o(a) l6 i/o(a) a7 i/o(h) c7 i/o(h) e7 i/o(h) g7 gnd j7 i/o(a) l7 gnd a8 ioctrl(h) c8 i/o(h) e8 i/o(h) g8 i/o(h) j8 vcc l8 gnd a9 i/o(h) c9 ioctrl(h) e9 i/o(h) g9 i/o(h) j9 gnd l9 gnd a10 i/o(h) c10 i/o(h) e10 i/o(h) g10 i/o(h) j10 vcc l10 gnd a11 i/o(h) c11 i/o(h) e11 vded2 g11 i/o(g) j11 vcc l11 gnd a12 tck c12 i/o(h) e12 i/o(g) g12 gnd j12 gnd l12 gnd a13 i/o(g) c13 i/o(g) e13 i/o(g) g13 i/o(g) j13 vcc l13 gnd a14 i/o(g) c14 i/o(g) e14 i/o(g) g14 i/o(g) j14 gnd l14 vcc a15 i/o(g) c15 i/o(g) e15 ioctrl(g) g15 i/o(g) j15 vcc l15 vcc a16 i/o(g) c16 i/o(g) e16 i/o(g) g16 gnd j16 i/o(f) l16 clk(6) a17 i/o(g) c17 i/o(g) e17 inref(g) g17 vccio(f) j17 vccio(f) l17 vccio(f) a18 i/o(g) c18 i/o(g) e18 i/o(g) g18 i/o(f) j18 i/o(f) l18 i/o(f) a19 i/o(f) c19 i/o(f) e19 i/o(f) g19 i/o(f) j19 i/o(f) l19 clk(8) a20 gnd c20 gndpll(0) e20 i/o(f) g20 i/o(f) j20 i/o(f) l20 i/o(f) a21 pllout(3) c21 i/o(f) e21 i/o(f) g21 inref(f) j21 i/o(f) l21 i/o(f) a22 i/o(f) c22 i/o(f) e22 i/o(f) g22 i/o(f) j22 i/o(f) l22 i/o(f) b1 i/o(a) d1 i/o(a) f1 i/o(a) h1 i/o(a) k1 tdi m1 i/o(b) b2 gnd d2 i/o(a) f2 inref(a) h2 i/o(a) k2 i/o(a) m2 i/o(b) b3 gndpll(3) d3 i/o(a) f3 i/o(a) h3 i/o(a) k3 i/o(a) m3 i/o(b) b4 gnd d4 i/o(a) f4 i/o(a) h4 i/o(a) k4 i/o(a) m4 clk(3)/pllin(1) b5 i/o(a) d5 i/o(a) f5 i/o(a) h5 ioctrl(a) k5 i/o(a) m5 i/o(b) b6 i/o(h) d6 i/o(h) f6 vccio(a) h6 vccio(a) k6 vccio(a) m6 vccio(b) b7 i/o(h) d7 i/o(h) f7 vccio(h) h7 i/o(h) k7 i/o(a) m7 clk(1) b8 inref(h) d8 i/o(h) f8 i/o(h) h8 gnd k8 vcc m8 vcc b9 i/o(h) d9 i/o(h) f9 vccio(h) h9 vcc k9 vcc m9 vcc b10 i/o(h) d10 i/o(h) f10 i/o(h) h10 vcc k10 gnd m10 gnd b11 i/o(h) d11 i/o(h) f11 vccio(h) h11 vded k11 gnd m11 gnd b12 i/o(g) d12 i/o(g) f12 vccio(g) h12 gnd k12 gnd m12 gnd b13 i/o(g) d13 i/o(g) f13 i/o(g) h13 vcc k13 gnd m13 gnd b14 i/o(g) d14 i/o(g) f14 vccio(g) h14 vcc k14 vcc m14 gnd b15 i/o(g) d15 ioctrl(g) f15 i/o(g) h15 gnd k15 vcc m15 gnd b16 i/o(g) d16 i/o(g) f16 vccio(g) h16 i/o(f) k16 i/o(f) m16 gnd b17 i/o(g) d17 i/o(g) f17 i/o(g) h17 i/o(f) k17 i/o(f) m17 i/o(e) b18 i/o(g) d18 i/o(f) f18 i/o(f) h18 i/o(f) k18 i/o(f) m18 i/o(e) b19 pllrst(0) d19 vccpll(0) f19 i/o(f) h19 i/o(f) k19 i/o(f) m19 i/o(e) b20 i/o(f) d20 i/o(f) f20 ioctrl(f) h20 i/o(f) k20 i/o(f) m20 clk(7) b21 i/o(f) d21 i/o(f) f21 i/o(f) h21 i/o(f) k21 i/o(f) m21 clk(5)/pllin(3) b22 i/o(f) d22 i/o(f) f22 ioctrl(f) h22 i/o(f) k22 i/o(f) m22 tms
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 64 n1 i/o(b) p16 i/o(e) t9 i/o(c) v2 i/o(b) w17 i/o(d) aa10 i/o(c) n2 i/o(b) p17 i/o(e) t10 trstb v3 i/o(b) w18 i/o(e) aa11 i/o(c) n3 i/o(b) p18 i/o(e) t11 gnd v4 i/o(b) w19 i/o(e) aa12 i/o(d) n4 i/o(b) p19 i/o(e) t12 i/o(c) v5 i/o(b) w20 i/o(e) aa13 i/o(d) n5 i/o(b) p20 i/o(e) t13 i/o(d) v6 i/o(c) w21 i/o(e) aa14 i/o(d) n6 i/o(b) p21 i/o(e) t14 i/o(d) v7 i/o(c) w22 i/o(e) aa15 i/o(d) n7 i/o(b) p22 i/o(e) t15 i/o(d) v8 i/o(c) y1 i/o(b) aa16 i/o(d) n8 vcc r1 i/o(b) t16 gnd v9 i/o(c) y2 i/o(b) aa17 i/o(d) n9 vcc r2 inref(b) t17 i/o(e) v10 i/o(c) y3 vccpll(2) aa18 i/o(d) n10 gnd r3 i/o(b) t18 i/o(e) v11 i/o(c) y4 i/o(c) aa19 i/o(e) n11 gnd r4 i/o(b) t19 i/o(e) v12 vded2 y5 i/o(c) aa20 gndpll(1) n12 gnd r5 i/o(b) t20 i/o(e) v13 i/o(d) y6 i/o(c) aa21 i/o(e) n13 gnd r6 i/o(b) t21 ioctrl(e) v14 i/o(d) y7 i/o(c) aa22 i/o(e) n14 vcc r7 i/o(b) t22 i/o(e) v15 i/o(d) y8 ioctrl(c) ab1 i/o(b) n15 vcc r8 gnd u1 ioctrl(b) v16 inref(d) y9 i/o(c) ab2 gndpll(2) n16 i/o(e) r9 vcc u2 i/o(b) v17 i/o(d) y10 i/o(c) ab3 pllrst(2) n17 vccio(e) r10 vcc u3 ioctrl(b) v18 i/o(e) y11 i/o(d) ab4 i/o(b) n18 i/o(e) r11 gnd u4 i/o(b) v19 i/o(e) y12 i/o(d) ab5 i/o(b) n19 i/o(e) r12 vded u5 i/o(b) v20 i/o(e) y13 i/o(d) ab6 i/o(c) n20 i/o(e) r13 vcc u6 i/o(c) v21 i/o(e) y14 i/o(d) ab7 i/o(c) n21 i/o(e) r14 vcc u7 vccio(c) v22 i/o(e) y15 ioctrl(d) ab8 ioctrl(c) n22 i/o(e) r15 gnd u8 i/o(c) w1 i/o(b) y16 i/o(d) ab9 i/o(c) p1 i/o(b) r16 i/o(d) u9 vccio(c) w2 i/o(b) y17 i/o(d) ab10 i/o(c) p2 i/o(b) r17 vccio(e) u10 i/o(c) w3 i/o(b) y18 i/o(e) ab11 i/o(c) p3 i/o(b) r18 i/o(e) u11 vccio(c) w4 i/o(b) y19 pllout(0) ab12 i/o(d) p4 i/o(b) r19 i/o(e) u12 vccio(d) w5 i/o(b) y20 pllrst(1) ab13 i/o(d) p5 i/o(b) r20 i/o(e) u13 i/o(d) w6 i/o(c) y21 i/o(e) ab14 i/o(d) p6 vccio(b) r21 i/o(e) u14 vccio(d) w7 i/o(c) y22 i/o(e) ab15 i/o(d) p7 i/o(b) r22 i/o(e) u15 i/o(d) w8 i/o(c) aa1 tdo ab16 ioctrl(d) p8 vcc t1 i/o(b) u16 vccio(d) w9 i/o(c) aa2 pllout(1) ab17 i/o(d) p9 gnd t2 i/o(b) u17 vccio(e) w10 i/o(c) aa3 gnd ab18 i/o(d) p10 vcc t3 i/o(b) u18 i/o(e) w11 i/o(c) aa4 i/o(b) ab19 i/o(e) p11 gnd t4 i/o(b) u19 i/o(e) w12 i/o(d) aa5 i/o(c) ab20 gnd p12 vcc t5 i/o(b) u20 ioctrl(e) w13 i/o(d) aa6 i/o(c) ab21 vccpll(1) p13 vcc t6 vccio(b) u21 i/o(e) w14 i/o(d) aa7 i/o(c) ab22 i/o(e) p14 gnd t7 gnd u22 inref(e) w15 i/o(d) aa8 inref(c) p15 vded t8 i/o(c) v1 i/o(b) w16 i/o(d) aa9 i/o(c) table 35: 484 pbga pinout table (continued) ball function ball function ball function ball function ball function ball function
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 65 ql6600 - 516 pbga pinout diagram top bottom eclipse ql6600-4pb516c pin a1 corner
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 66 ql6600 - 516 pbga pinout table table 36: 516 pbga pinout table ball function ball function ball function ball function ball function ball function a1 gnd c1 i/o(f) e1 i/o(g) g1 i/o(g) l5 vcc p3 i/o(h) a2 i/o(f) c2 i/o(f) e2 i/o(g) g2 inref(g) l6 vcc p4 vcc a3 i/o(f) c3 i/o(f) e3 i/o(g) g3 i/o(g) l11 gnd p5 i/o(h) a4 i/o(f) c4 pllout(3) e4 vccpll(0) g4 i/o(g) l12 gnd p6 vccio(h) a5 i/o(f) c5 i/o(f) e5 i/o(f) g5 i/o(g) l13 gnd p11 gnd a6 i/o(f) c6 i/o(f) e6 i/o(f) g6 vccio(g) l14 gnd p12 gnd a7 ioctrl(f) c7 i/o(f) e7 i/o(f) g21 vccio(d) l15 gnd p13 gnd a8 i/o(f) c8 inref(f) e8 vcc g22 i/o(d) l16 gnd p14 gnd a9 i/o(f) c9 i/o(f) e9 i/o(f) g23 i/o(d) l21 vcc p15 gnd a10 i/o(f) c10 i/o(f) e10 i/o(f) g24 i/o(d) l22 i/o(d) p16 gnd a11 i/o(f) c11 i/o(f) e11 i/o(f) g25 i/o(d) l23 i/o(d) p21 vccio(c) a12 i/o(f) c12 i/o(f) e12 vcc g26 inref(d) l24 i/o(d) p22 i/o(c) a13 i/o(e) c13 clk(7) e13 i/o(f) h1 i/o(g) l25 i/o(d) p23 vcc a14 i/o(e) c14 i/o(e) e14 i/o(f) h2 i/o(g) l26 i/o(d) p24 i/o(c) a15 i/o(e) c15 i/o(e) e15 i/o(e) h3 ioctrl(g) m1 i/o(g) p25 i/o(c) a16 i/o(e) c16 i/o(e) e16 vcc h4 i/o(g) m2 i/o(g) p26 trstb a17 i/o(e) c17 i/o(e) e17 clk(6) h5 i/o(g) m3 i/o(g) r1 i/o(h) a18 ioctrl(e) c18 i/o(e) e18 i/o(e) h6 vcc m4 i/o(g) r2 i/o(h) a19 ioctrl(e) c19 i/o(e) e19 i/o(e) h21 vcc m5 i/o(g) r3 i/o(h) a20 i/o(e) c20 i/o(e) e20 i/o(e) h22 vcc m6 vccio(g) r4 i/o(h) a21 i/o(e) c21 i/o(e) e21 i/o(e) h23 i/o(d) m11 gnd r5 vcc a22 i/o(e) c22 i/o(e) e22 i/o(e) h24 ioctrl(d) m12 gnd r6 vcc a23 i/o(e) c23 i/o(e) e23 gndpll(1) h25 ioctrl(d) m13 gnd r11 gnd a24 i/o(e) c24 i/o(e) e24 i/o(e) h26 i/o(d) m14 gnd r12 gnd a25 pllrst(1) c25 i/o(e) e25 i/o(d) j1 i/o(g) m15 gnd r13 gnd a26 gnd c26 i/o(e) e26 i/o(d) j2 i/o(g) m16 gnd r14 gnd b1 i/o(f) d1 i/o(g) f1 ioctrl(g) j3 i/o(g) m21 vccio(d) r15 gnd b2 pllrst(0) d2 i/o(g) f2 i/o(g) j4 i/o(g) m22 vcc r16 gnd b3 i/o(f) d3 i/o(f) f3 i/o(g) j5 i/o(g) m23 i/o(d) r21 vcc b4 i/o(f) d4 i/o(f) f4 i/o(g) j6 vccio(g) m24 i/o(d) r22 i/o(c) b5 i/o(f) d5 gndpll(0) f5 i/o(f) j21 vccio(d) m25 i/o(d) r23 i/o(c) b6 i/o(f) d6 i/o(f) f6 gnd j22 i/o(d) m26 i/o(d) r24 i/o(c) b7 ioctrl(f) d7 i/o(f) f7 vccio(f) j23 i/o(d) n1 tck r25 i/o(c) b8 i/o(f) d8 i/o(f) f8 vcc j24 i/o(d) n2 i/o(h) r26 i/o(c) b9 i/o(f) d9 i/o(f) f9 vccio(f) j25 i/o(d) n3 i/o(g) t1 i/o(h) b10 i/o(f) d10 i/o(f) f10 gnd j26 i/o(d) n4 i/o(g) t2 i/o(h) b11 i/o(f) d11 i/o(f) f11 vcc k1 i/o(g) n5 i/o(g) t3 i/o(h) b12 i/o(f) d12 i/o(f) f12 vccio(f) k2 i/o(g) n6 gnd t4 i/o(h) b13 clk(5)/ pllin(3) d13 tms f13 gnd k3 i/o(g) n11 gnd t5 i/o(h) b14 i/o(e) d14 i/o(e) f14 vccio(e) k4 i/o(g) n12 gnd t6 vcc b15 i/o(e) d15 i/o(e) f15 vcc k5 i/o(g) n13 gnd t11 gnd b16 i/o(e) d16 i/o(f) f16 vcc k6 gnd n14 gnd t12 gnd b17 i/o(e) d17 i/o(e) f17 gnd k21 gnd n15 gnd t13 gnd b18 inref(e) d18 i/o(f) f18 vccio(e) k22 i/o(d) n16 gnd t14 gnd b19 i/o(e) d19 clk(8) f19 vcc k23 i/o(d) n21 gnd t15 gnd b20 i/o(e) d20 i/o(e) f20 vccio(e) k24 i/o(d) n22 i/o(d) t16 gnd b21 i/o(e) d21 i/o(e) f21 gnd k25 i/o(d) n23 i/o(d) t21 vcc b22 i/o(e) d22 i/o(e) f22 i/o(e) k26 i/o(d) n24 i/o(d) t22 vcc b23 i/o(e) d23 vccpll(1) f23 i/o(d) l1 i/o(g) n25 i/o(d) t23 i/o(c) b24 i/o(e) d24 i/o(e) f24 i/o(d) l2 i/o(g) n26 i/o(d) t24 i/o(c) b25 i/o(e) d25 i/o(e) f25 i/o(d) l3 i/o(g) p1 i/o(h) t25 i/o(c) b26 pllout(0) d26 i/o(d) f26 i/o(d) l4 i/o(g) p2 i/o(h) t26 i/o(c)
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 67 u1 i/o(h) w25 inref(c) aa21 gnd ac3 i/o(a) ad11 i/o(a) ae19 i/o(b) u2 i/o(h) w26 i/o(c) aa22 vccpll(2) ac4 i/o(a) ad12 tdi ae20 i/o(b) u3 i/o(h) y1 i/o(h) aa23 i/o(c) ac5 i/o(a) ad13 clk(4) dedclk/ pllin(0) ae21 i/o(b) u4 i/o(h) y2 i/o(h) aa24 i/o(c) ac6 i/o(a) ad14 i/o(a) ae22 i/o(b) u5 i/o(h) y3 i/o(h) aa25 i/o(c) ac7 i/o(a) ad15 i/o(b) ae23 i/o(b) u6 gnd y4 i/o(h) aa26 i/o(c) ac8 i/o(a) ad16 i/o(b) ae24 i/o(b) u21 gnd y5 i/o(h) ab1 i/o(h) ac9 i/o(a) ad17 i/o(b) ae25 pllrst(2) u22 i/o(c) y6 vccio(h) ab2 i/o(h) ac10 i/o(a) ad18 inref(b) ae26 i/o(b) u23 i/o(c) y21 vccio(c) ab3 i/o(a) ac11 i/o(a) ad19 i/o(b) af1 i/o(a) u24 i/o(c) y22 i/o(c) ab4 gndpll(3) ac12 i/o(a) ad20 i/o(b) af2 i/o(a) u25 i/o(c) y23 i/o(c) ab5 vccpll(3) ac13 i/o(a) ad21 i/o(b) af3 i/o(a) u26 i/o(c) y24 i/o(c) ab6 i/o(a) ac14 clk(1) ad22 i/o(b) af4 i/o(a) v1 i/o(h) y25 i/o(c) ab7 i/o(a) ac15 i/o(b) ad23 i/o(b) af5 i/o(a) v2 ioctrl(h) y26 ioctrl(c) ab8 i/o(a) ac16 i/o(b) ad24 gnd af6 ioctrl(a) v3 ioctrl(h) aa1 i/o(h) ab9 i/o(a) ac17 i/o(b) ad25 i/o(b) af7 i/o(a) v4 i/o(h) aa2 i/o(h) ab10 i/o(a) ac18 i/o(b) ad26 i/o(b) af8 i/o(a) v5 i/o(h) aa3 i/o(h) ab11 vcc ac19 i/o(b) ae1 gnd af9 i/o(a) v6 vccio(h) aa4 i/o(a) ab12 i/o(a) ac20 i/o(b) ae2 gnd af10 i/o(a) v21 vccio(c) aa5 i/o(a) ab13 i/o(a) ac21 i/o(b) ae3 i/o(a) af11 i/o(a) v22 i/o(c) aa6 gnd ab14 clk(3)/ pllin(1) ac22 tdo ae4 i/o(a) af12 clk(2)/ pllin(2) v23 i/o(c) aa7 vccio(a) ab15 vcc ac23 pllout(1) ae5 i/o(a) af13 i/o(b) v24 ioctrl(c) aa8 vcc ab16 i/o(b) ac24 i/o(b) ae6 i/o(a) af14 i/o(b) v25 i/o(c) aa9 vccio(a) ab17 i/o(b) ac25 i/o(b) ae7 inref(a) af15 i/o(b) v26 i/o(c) aa10 gnd ab18 i/o(b) ac26 i/o(c) ae8 i/o(a) af16 i/o(b) w1 inref(h) aa11 vcc ab19 vcc ad1 i/o(a) ae9 i/o(a) af17 i/o(b) w2 i/o(h) aa12 vccio(a) ab20 i/o(b) ad2 pllout(2) ae10 i/o(a) af18 i/o(b) w3 i/o(h) aa13 gnd ab21 i/o(b) ad3 pllrst(3) ae11 i/o(a) af19 ioctrl(b) w4 i/o(h) aa14 vccio(b) ab22 gndpll(2) ad4 i/o(a) ae12 clk(0) af20 ioctrl(b) w5 vcc aa15 vcc ab23 i/o(b) ad5 i/o(a) ae13 i/o(b) af21 i/o(b) w6 vcc aa16 vcc ab24 i/o(c) ad6 i/o(a) ae14 i/o(b) af22 i/o(b) w21 vcc aa17 gnd ab25 i/o(c) ad7 i/o(a) ae15 i/o(b) af23 i/o(b) w22 i/o(c) aa18 vccio(b) ab26 i/o(c) ad8 ioctrl(a) ae16 i/o(b) af24 i/o(b) w23 i/o(c) aa19 vcc ac1 i/o(a) ad9 i/o(a) ae17 i/o(b) af25 i/o(b) w24 i/o(c) aa20 vccio(b) ac2 i/o(a) ad10 i/o(a) ae18 i/o(b) af26 i/o(b) table 36: 516 pbga pinout table (continued) ball function ball function ball function ball function ball function ball function
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 68 package mechanical drawings 208 pqfp packaging drawing
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 69 280 lfbga packaging drawing
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 70 484 pbga packaging drawing
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 71 516 pbga packaging drawing
www.quicklogic.com ? 2007 quicklogic corporation ? ? ? ? ? ? eclipse family data sheet rev. f 72 packaging information eclipse product is offered in the fo llowing packages. all packages support commercial, industrial, and military temperature ranges. the eclipse product family packaging information is presented in table 37 . ordering information contact information phone: (408) 990-4000 (us) (905) 940-4149 (canada) +(44) 1932 57 9011 (europe) +(86) 21 6867 0273 (asia ? except japan) +(81) 45 470 5525 (japan) e-mail: info@quicklogic.com sales: www.quicklogic.com/sales support: www.quicklogic.com/support internet: www.quicklogic.com table 37: packaging options device information ql6250 and ql6325 ql6500 and ql6600 pin/ball pitch pin/ball pitch package definitions a a. pqfp = plastic quad flat pack lfbga = low profile fine pitch ball grid array pbga = plastic ball grid array 208 pqfp 0.50 mm 280 lfbga 0.80 mm 280 lfbga 0.80 mm 484 pbga 1.0 mm 484 pbga 1.0 mm 516 pbga 1.27 mm ql 6250 - 7 pq20 8 c q u icklogic device eclip s e device p a rt n u m b er 6250, 6 3 25, 6500, a nd 6600 s peed gr a de 4 = q u ick 5 = f as t 6 = f as ter 7 = f as te s t oper a ting r a nge c = commerci a l i = ind us tri a l m = milit a ry p a ck a ge pq20 8 (pqn20 8 )* = 20 8 -pin pqfp pt2 8 0 (ptn2 8 0)* = 2 8 0- ba ll lfbga (0. 8 mm) p s 4 8 4 (p s n4 8 4)* = 4 8 4- ba ll fpbga (1.0 mm) pb516 (pbn516)* = 516- ba ll pbga (1.27 mm) * le a d-free p a ck a ging i s a v a il ab le, cont a ct q u icklogic reg a rding a v a il ab ility ( s ee cont a ct inform a tion).
? 2007 quicklogic corporation www.quicklogic.com ? ? ? ? ? ? eclipse family data sheet rev. f 73 revision history copyright information copyright ? 2007 quicklogic corpor ation. all rights reserved. the information contained in this document and is protected by copyright. all righ ts are reserved by quicklogic corporation. qu icklogic corporation reserves the right to modify this document without an y obligation to notify any person or entity of such revision. copying, duplicating, selling, or otherwis e distributing any part of this product without the prior written consent of an authorized rep resentative of quicklogic is prohibited. quicklogic and the quicklogic logo, pasic, quickworks are registered trademarks of quicklogic corporation; eclipse, is a trademark of quicklogic corporation. revision date comments a jan 2002 first release. b april 2003 brian faith and kathleen murchek c may 2003 brian faith and kathleen murchek d september 2005 brian faith, mehul kochar, and kathleen murchek combined previous eclipse family data sheet with ql6250, ql6325, ql6500, and ql6600 data sheets to cr eate one complete eclipse family data sheet. e march 2007 jason lew and kathleen murchek changed pin g16 from vpump to gnd in all ps484 pinout tables. f september 2007 kathleen murchek updated packaging information to include lead-free parts. updated banner and logo.

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