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| 9128i-rke-04/14 features fully integrated fractional-n pll ask and closed loop fsk modulation output power up to +12.5dbm from 300mhz to 450mhz current consumption is scaled by output power programming fast crystal oscillator start-up time of typically 200s low current consumption of typically 7.3ma at 5.5dbm only one 13.0000mhz crystal for 314.1mhz to 329.5mhz and 424.5mhz to 439.9mhz operation single ended rf power amplifier output many software programmable options using spi output power from ?0.5dbm to +12.5dbm rf frequency from 300mhz to 450mhz with different crystals fsk deviation with 396hz resolution clk output frequency 3.25mhz or 1.625mhz data rate up to 40kbit/s (manchester) 4kv hbm esd protection including xto operating temperature range of ?40c to +125c supply voltage range of 1.9v to 3.6v tssop10 package benefits robust crystal oscillator with fast start up and high reliability lower inventory costs and reduced part number proliferation longer battery lifetime supports multi-channel operation wide tolerance crystal possible with pll software compensation ata5749/ata5749c fractional-n pll transmitter ic datasheet
ata5749/ata5749c [datasheet] 9128i?rke?04/14 2 1. description the atmel ? ata5749 is a fractional-n-pll transmitter ic for 300mhz to 450mhz operation and is especially targeted for tire pressure sensor gauges, remote keyle ss entry, and passive entry and other automo tive applications. it operates at data rates up to 40kbit/s manchester for ask and fsk with a ty pical 5.5dbm output power at 7.3ma. transmitter parameters such as output power, output frequency, fsk deviation, and current consumption can be programmed using the spi interface. this fully integrated pll trans mitter ic simplifies rf board design and results in very low material costs. figure 1-1. block diagram clk_drv pfd ask_mod 433_n315 freq[0:14] pwr[0:3] fsk_mod div_cntrl sck xto2 xto1 vs gnd en ant2 ant1 sdin_txdin clk xto_rdy 3 4 5 2 1 8 7 6 9 10 fractional-n-pll clk_on fsep[0:7] 4 or 8 1 digital control and registers frac. div. xto (fox) power up/down cp lp vco pa atmel ata5749 xto signal 3 ata5749/ata5749c [datasheet] 9128i?rke?04/14 2. pin configuration figure 2-1. tssop 10 package pinout table 2-1. pin description pin symbol function 1 clk clk output 2 sdin_txdin serial bus data input and tx data input 3 sck serial bus clock input 4 ant2 antenna interface 5 ant1 antenna interface 6 xto2 crystal/c load2 connection 7 xto1 crystal/c load1 connection 8 vs supply input 9 gnd supply gnd 10 en enable input 6 7 8 9 10 xto2 xto1 vs gnd en ant1 ant2 sck sdin_txdin clk 5 4 3 2 1 ata5749 atmel ata5749/ata5749c [datasheet] 9128i?rke?04/14 4 3. functional description 3.1 fractional-n pll the atmel ? ata5749 block diagram is shown in figure 1-1 on page 2 . the operation of the pll is determined by the contents of a 32-bit conf iguration register. the 15-bit value freq is us ed with the 1-bit 434_n315 flag to determine the rf carrier frequency. this results in a user-s electable frequency step size of 793hz (with 13.000mhz crystal). with this level of resolution, it is possible to compensate for crystal tolerance by adjusting the value of freq accordingly. this enables the use of lower cost crystals without compromi sing final accuracy. in addition, software programming of rf carrier frequency allows this device to be used in some multi-channel applications. modulation type is selected with the 1-bit ask_nfsk flag. fsk modu lation is achieved by modifying the divider block in the feedback loop. the benefit to this approach is that performance- reducing rf spurs (c ommon in applications that create fsk by ?pulling? the l oad capacitance in the cryst al oscillator circuit) are completely el iminated. the 8-bit value fsep establishe s the fsk frequency deviation. it is possibl e to obtain fsk frequency deviations from 396hz to 101khz in steps of 396hz. the pll lock time is 1280/(external crystal frequency) and amounts to 98.46s when using a 13.0000mhz crystal. when added to the crystal oscillator start-up time, a very fast time -to-transmit is possible (typically 300s). this feature extends battery life in applications like tire pressure monitoring s ystems, where the message length is often shorter than 10ms and the time ?wasted? during start-up and se ttling time becomes more significant. 3.2 selecting the rf carrier frequency the fractional divider can be programmed to generate an rf output frequency f rf according to the formulas shown in table 3-1 . note that in the case of f rf ask , the fsep/2 value is rounded down to the next integer value if fsep is an odd number. fsep can take on the values of 1 to 255. using a 13.000mhz crystal, the ran ge of frequency deviation f dev_fsk is programmable from 396hz to 101.16khz in steps of 396hz . for example, with fsep = 100 the output frequency is fsk modulated with f dev_fsk = 39.6khz. freq can take values in the range of values 2500 and 22000. using a 13.0000mhz cr ystal, the output frequency f rf can be programmed to 315mhz by setting freq[0:14] = 3730, fsep[0:7] = 100 and s434_n315 = 0. by setting freq[0:14] = 14342, fsep[0:7] = 100 and s434_n315 = 1, 433.92mhz can be realized. table 3-1. rf output parameter formulas rf output parameter s434_n315 = low s434_n315 = high f rf_fsk_low (24 + (freq + 0.5)/16384) f xto (32.5 + (freq + 0.5)/16384) f xto f rf_fsk_high (24 + (freq + fsep + 0.5)/16384) f xto (32.5 + (freq + fsep + 0.5)/16384) f xto f dev__fsk fsep/32768 f xto fsep/32768 f xto f rf ask (24 + (freq + fsep/2 + 0.5)/16384) f xto (32.5 + (freq + fsep/2 + 0.5)/16384) f xto 5 ata5749/ata5749c [datasheet] 9128i?rke?04/14 the pa is enabled when the pll is locked a nd the configuration register programmi ng is completed. upon enabling pa at fsk-mode, the rf output power will be switched on. at ask mo de, the input signal must be additionally set high for rf at output pins. the output power is user pr ogrammable from ?0.5dbm to +12.5dbm in steps of approximately 1db. changing the output power requirements, yo u also modify the current cons umption. this gives the user the option to optimize system performance (rf link budget versus battery life). the pa is im plemented as a class-c amplifier, which uses an open- collector output to deliver a current pulse that is nearly independent from supply voltage and temperature. the working principle is shown in figure 3-1 . figure 3-1. class c power amplifier output the peak value of this current pulse i pulse is calibrated during atmel ? ata5749 production to about 20%, which corresponds to about 1.5db variation in output power for a give n power setting under typical conditions. the actual value of i pulse can be programmed with the 4-bit value in pwr. this al lows the user to scale both the output power and current consumption to optimal levels. ask modulation is achieved by using the sdin_txdin signal wh ere a high on this pin corresponds to rf carrier ?on? and a low corresponds to rf ?off?. fsk uses the same signal path but high switch on the upper fsk-frequency. 4 5 power meter ant2 50 ant1 c2 l1 v ant1 v ant1 z lopt v s v s i ant2 i ant2 i pulse = (pwr[0:3]) ata5749/ata5749c [datasheet] 9128i?rke?04/14 6 3.3 crystal oscillator the crystal oscillator (xto) is an amplitude-regulated pierce oscillator. it has fixed functi on and is not programmable. the oscillator is enabled when the en is ?set ?. after the oscillator?s output amplitude reaches an acceptable level, the xto_rdy flag is ?set?. the clk-pin becomes active if clk_on is set. the pll receives its reference frequency. typically, this process takes about 200s when using a small sized crystal with a motional capacitance of 4ff. this start-up time strongly depends on the motional capacitance of the crystal and is lo wer with higher motional capacitance. the high negative starting impedance of r xto12_start > 1500 is important to minimize the failure rate due to the ?sleeping crystal? phenomena (more common among very small sized 3.2mm 2.5mm crystals). 3.4 clock driver the clock driver block shown in figure 1-1 on page 2 is programmed using the clk_only, clk_on, and div_cntrl bits in the configuration register. when clk_only is ?clear?, norma l operation is selected and the fr actional-n pll is operating. when clk_on is ?set?, the clk output is enabled. the crystal clock divider ratio can be se t to divide by four when div_cntrl is ?set? and divide by eight when div_cntrl is ?clear?. with a 13.000 0mhz crystal, this yields an output of 3.25mhz or 1.625mhz, respectively. when clk_on is ?clear?, no clock is available at clk and the transmitter has less current consumption. the clk signal can be used to clock a microcontroller. it is cm os compatible and can drive up to 20pf of load capacitance at 1.625mhz and up to 10pf at 3.25mhz. when the device is in power-down mode, the clk output stays low. upon power up, clk output remains low until the amplit ude detector of the crystal oscillator det ects sufficient amplitude and xto_rdy and clk_on are ?set?. after this ta kes place, clk output becomes active. the clk output is synchronized with the xto_rdy signal so that the first period of the clk output is always a full period (no cl k output spike at activation). to lower overall current consumption, it is possible to power do wn the entire chip except for the crystal oscillator block. thi s can be achieved when the clk_only is ?set?. 7 ata5749/ata5749c [datasheet] 9128i?rke?04/14 4. application 4.1 typical application figure 4-1. typical application circuit figure 4-1 shows the typical application circuit. for c6, the supp ly-voltage blocking capacitor, value of 68nf x7r is recommended. c2 and c3 are npo capacitors used to match the loop antenna impedance to th e power amplifier optimum load impedance. they are based on the pcb trace antenna and are 20pf npo capacitors. c1 (typically 1nf x7r) is needed for the supply blocking of the pa. in combination with l1 (200nh to 300nh), they prevent the power amplifier from coupling to the supply voltage and disturbing pll operation. they should be placed close to pin 5. l1 also provides a low resistive path to v s to deliver the dc current to ant1. clk_drv pfd ask_mod 433_n315 freq[0:14] pwr[0:3] fsk_mod div_cntrl sck xto2 xto1 xtal vs gnd en ant2 ant1 sdin_txdin clk xto_rdy clk io3 io2 io1 3 4 c1 vs vs c2 c3 c5 c4 c6 l1 5 2 1 8 7 6 9 10 fractional-n-pll clk_on fsep[0:7] 4 or 8 1 digital control and registers frac. div. xto (fox) power up/down cp lp vco pa loop antenna micro- controller atmel ata5749 xto signal ata5749/ata5749c [datasheet] 9128i?rke?04/14 8 the pcb loop antenna should not exceed a trace width of 1.5 mm otherwise the q-factor of th e loop antenna is too high. c4 and c5 should be selected so that the xto runs on the load resonance frequency of the crystal. a crystal with a load capacitance of 9pf is recommended for proper start-up behavio r and low current consumption. when determining values for c4 and c5, a parasitic capacitance of 3pf should be included. with value of 15pf for c4 and c5, an effective load capacitance of 9pf can be achieved, e.g., 9pf = (15pf + 3pf)/2. the supply v s is typically delivered from a single li-cell. 4.1.1 antenna impedance matching the maximum output power is achieved by using load impedances according to table 4-1 on page 9 and table 4-2 on page 9 and the output power. the load impedance z lopt is defined as the impedance seen from the atmel ? ata5749 ant1, ant2 into the matching network. this is not th e output impedance of the ic but essentially the peak voltage divided by the peak current with some additional parasitic effects (cpar). table 4-1 on page 9 and table 4-2 on page 9 do not contain information pertaining to c3 in figure 4-2 , which is an option for better matching at low power steps. figure 4-2 is the circuit that was used to obtain the typical output power measurements in figure 4-3 on page 10 and typical current consumption in figure 4-4 on page 10 . table 4-1 and table 4-2 on page 9 provide recommended values and performance info at various output power levels. for reference, z lopt is defined as the impedance seen from the atmel ata5749 ant1, ant2 into the matching network. figure 4-2. output powe r measurement circuit 5 4 power meter ant1 50 ant2 pa c2 c3 c1 l1 z lopt vs 9 ata5749/ata5749c [datasheet] 9128i?rke?04/14 the used parts at table 4-1 and table 4-2 are: inductors: high q coilcraft 0805 cs; capacitors: avx accu-p 0402 table 4-1. measured pa matching at 315m hz (clk_on = ?low?) at typ. samples pwr register desired power (dbm) l1 (nh) c2 (pf) c3 1) (pf) r lopt ( ) z lopt ( ) cpar (pf) actual power (dbm) 3 ?0.5 110 1.2 1.6 2950 110 + 540j 0.9 ?0.37 4 1.0 100 1.5 --- 1940 150 + 520j 0.9 1.12 5 2.5 100 1.5 --- 1550 190 + 520j 0.9 2.11 6 3.5 100 1.5 --- 1250 220 + 480j 0.9 3.23 7 4.5 82 1.8 --- 1000 240 + 430j 0.9 4.38 8 5.5 82 2.2 --- 730 280 + 360j 0.9 5.42 9 6.5 68 2.7 --- 580 290 + 300j 0.9 7.14 10 7.5 68 2.7 --- 460 290 + 290j 0.9 8.22 11 8.5 68 3.3 --- 350 280 + 225j 0.9 8.63 12 9.5 56 3.6 --- 320 250 + 150j 0.9 9.79 13 10.5 47 4.7 --- 250 215 + 85j 0.9 10.52 14 11.5 47 5.6 --- 190 180 + 50j 0.9 11.67 15 12.5 47 5.6 --- 160 160 + 45j 0.9 13 note: 1. leave capacitor ou t at row without value table 4-2. measured pa matching at 433. 92mhz (clk_on = ?low?) at typ. samples pwr register desired power (dbm) l1 (nh) c2 (pf) c3 1) (pf) r lopt ( ) z lopt ( ) cpar (pf) actual power (dbm) 3 ?0.5 68 0,9 1.5 2800 60 + 400j 0.9 ?0.62 4 1.0 56 2.7 + 2.2 --- 1850 90 + 390j 0.9 1.3 5 2.5 56 1.2 --- 1450 110 + 380j 0.9 2.73 6 3.5 47 1.8 5.6 1150 130 + 370j 0.9 3.03 7 4.5 47 1.6 --- 950 150 + 350j 0.9 4.63 8 5.5 47 1.8 --- 680 180 + 300j 0.9 6.18 9 6.5 43 2.2 1 560 200 + 270j 0.9 6.66 10 7.5 36 2.4 --- 450 210 + 230j 0.9 7.91 11 8.5 33 3 --- 340 200 + 170j 0.9 8.68 12 9.5 36 2.7 --- 310 195 + 150j 0.9 9.8 13 10.5 36 3.6 --- 230 175 + 100j 0.9 10.49 14 11.5 27 4.7 --- 180 150 + 70j 0.9 11.6 15 12.5 27 4.7 --- 150 130 + 50j 0.9 12.5 note: 1. leave capacitor ou t at row without value ata5749/ata5749c [datasheet] 9128i?rke?04/14 10 figure 4-3. typical measured output power figure 4-4. typical current consumption i at port vs 11 9 3 1 85 433mhz 315mhz 125 27 -40 7 5 15 13 temperature [ c] pmeas [dbm] v s = 3.0v, pwr[0:15] = 15 v s = 1.9v, pwr[0:15] = 8 v s = 1.9v, pwr[0:15] = 15 v s = 3.6v, pwr[0:15] = 15] v s = 3.6v, pwr[0:15] = 8 v s = 3.0v, pwr[0:15] = 8 5 7 9 11 13 15 17 19 21 23 5 2 1 5 8 7 2 0 4 - ivs [ma] 315mhz 433mhz v s = 3.6v, pwr[0:15] = 15 v s = 3.0v, pwr[0:15] = 15 v s = 1.9v, p wr[0:15] = 15 v s = 3.6v, pwr[0:15] = 8 v s = 3.0v, p wr[0:15] = 8 v s = 1.9v, pwr[0:15] = 8 temperature [ ? c] 11 ata5749/ata5749c [datasheet] 9128i?rke?04/14 5. pulling of frequency due to ask modulation (pa switching) the switching effect on vco fr equency in ask mode is very low if a correct pc b layout and dec oupling is used . therefore, power ramping is not needed to achieve a clean spectrum (see figure 5-1 ). figure 5-1. typical rf spectrum of 4 0khz ask modulation at pout = 12.5dbm ata5749/ata5749c [datasheet] 9128i?rke?04/14 12 6. configuration register 6.1 general description the user must program all 32 bits of the configuration register upon power up (en = high) or whenever changes to operating parameters are desired. the configuration regist er bit assignments and descriptions can be found in table 6-1 and table 6-2 . table 6-1. organization of the control register msb 31 clk_ only 30 s434_ n315 29 freq [14] 28 freq [13] 27 freq [12] 26 freq [11] 25 freq [10] 24 freq [9] 23 freq [8] 22 freq [7] 21 freq [6] 20 freq [5] 19 freq [4] 18 freq [3] 17 freq [2] 16 freq [1] frequency adjust = freq[0..14] freq[0] + 2 freq[1] + 4 freq[2] + ... + freq[14] 16384 = 0..32767 lsb 15 freq [0] 14 fsep [7] 13 fsep [6] 12 fsep [5] 11 fsep [4] 10 fsep [3] 9 fsep [2] 8 fsep [1] 7 fsep [0] 6 div_ cntrl 5 pwr [3] 4 pwr [2] 3 pwr [1] 2 pwr [0] 1 ask_ nfsk 0 clk_ on fsk shift = fsep[0..7] fsep[0] + ... + fsep[7] 128 = 0..255 output power = pwr[0..3] pwr[0] + .. + pwr[3] 8 = 0..15 table 6-2. control register functional descriptions name bit no. size remarks clk_only 31 1 activates/deactivates clk_only mode low = normal mode high = clock only mode ( figure 4-1 on page 7 ) s434_n315 30 1 vco band selection high = 367mhz to 450mhz low = 300mhz to 368mhz freq[0:14] 15 ... 29 15 pll frequency adjust see table 6-1 for formula fsep[0:7] 7 ... 14 8 fsk deviation adjust see table 6-1 for formula div_cntrl 6 1 clk output divider ratio low = f xto /8 high = f xto /4 pwr[0:3] 2 ... 5 4 pa output power adjustment see table 4-1 and table 4-2 on page 9 ask_nfsk 1 1 modulation type low = fsk high = ask clk_on 0 1 clk_drv port control high = clk port is on low = clk port is off 13 ata5749/ata5749c [datasheet] 9128i?rke?04/14 6.2 programming the configuration register is programmed serially using the spi bus, starting with the msb. it consists of the enable line (en), the data line (sdin_txdin), and th e spi-bus clock (sck). the sdin_txdin data is loaded on the positive edge of the sck. the contents of the c onfiguration register become programmed on the negative sck edge of the last bit (lsb) of the programming sequence. the timing of this bus is shown in figure 6-1 . note that the maximum usable clock speed on the spi bus is limited to 2mhz. figure 6-1. spi bus timing at the conclusion of the 32 bit programming sequence, the sdin_txdin line becomes the mo dulation input for the rf transmitter. after programming is complete, the sck signal has no effect on the device. to disable the transmitter and enter the off mode, en and sdin_txdin must be returned to the low state. for clarity, several additional timing diagrams are included. figure 6-2 shows the situation when the programming terminates faster then the xto is ready. figure 6-2. timing diagram if register programming is faster than t xto t setup t en_setup t sck_low t sck_high t sck_cycle t sdin_txdin_setup t hold sdin_txdin sck x x msb-1 msb en t xto t pll x x x fsk; tx_mode2 ask: tx_mode1 and tx_mode2 tx-data off_ mode off_mode tx_ mode1 start_up_ mode_2 start_up_ mode_1 32-bit configuration clk (output) sck (input) en (input) pa (output power) sdin_txdin (input) ata5749/ata5749c [datasheet] 9128i?rke?04/14 14 figure 6-3 shows the combination with slow programming and a faster ramp up of xto. a diagram of the operating modes is shown in figure 6-5 on page 16 and a description of which circuit blocks are active is provided in table 6-3 on page 15 . this also contains the information needed for the calculation of consumed charge for one operation cycle. figure 6-3. timing diagram if programming is slower than t xto 6.3 reprogramming without stopping the crystal oscillator after the configuration register is progr ammed and rf data transmission is comple ted, the off mode is normally entered. this stops the crystal oscillator and pll. if it is desirable to modify the contents of the configuration register without ente ring the off mode, the reset_register_mode can be used. to en ter the reset_register_mode, the sdin_txdin must be asserted high while the en is asserted low for at least 10s reset_ min time. this state is shown in figure 6-4 on page 15 , state diagram of operating modes. in reset_register_mode, the pa and fractional pll remain off but the xto remains active. this state must stay for minimum 10s. at the next step you must rise first en and sdin_txdin 10s delayed. while in this mode, the 32 bi t configuration register data can be sent on the spi bus as shown in figure 6-2 on page 13 . after data transmission, the device can be switched back to off_mode by asserting en, sck, and sdin_txdin to a low state. an example of programming from the reset_ register_mode is shown in figure 6-4 on page 15 . t xto t pll x x fsk; tx_mode2 ask: tx_mode1 and tx_mode2 tx-data off_ mode off_mode tx_ mode1 start_up_ mode_2 start_up_ mode_1 32-bit configuration clk (output) sck (input) en (input) pa (output power) sdin_txdin (input) 15 ata5749/ata5749c [datasheet] 9128i?rke?04/14 figure 6-4. timing diagram when using reset_register_mode table 6-3. active circuits as a function of operating mode operating mode active circuit blocks off_mode -none- start_up_mode_1 power up/down; xto; digital control start_up_mode_2 power up/down; xto; digital control; fractional-n-pll tx_mode1 power up/down; xto; digital control; fractional-n-pll; clk_drv (1) tx_mode2 power up/down; xto; digital control; fractional-n-pll; clk_drv (1) ; pa clock_only_mode power up/down; xto; digital control; clk_drv (1) reset_register_mode power up/down; xto; digital control; clk_drv (1) configuration_mode_1 power up/down; xto; digital control; clk_drv (1) configuration_mode_2 power up/down; xto; digital control; clk_drv (1) ; fractional-n-pll note: 1. only if activated with clk_on = high t sdin_txdin_setup t en_setup t en_reset t pll fsk; tx_mode2 ask: tx_mode1 and tx_mode2 fsk; tx_mode2 ask: tx_mode1 and tx_mode2 off_ mode con- figuration_ mode_2 con- figuration_ mode_1 reset_ register_ mode start_up_ mode_2 start_up_ mode_1 tx_mode1 tx_mode1 32-bit configuration 32-bit configuration tx_ data tx_ data clk (output) sck (input) en (input) pa (output power) sdin_txdin (input) t pll ata5749/ata5749c [datasheet] 9128i?rke?04/14 16 figure 6-5. state diagram of operating modes start-up_mode_2 clk_only = 'low' register parity programmed 1 clk_only = 'low' register parity programmed 1 clk_only = 'low' register programmed 2 xto_rdy = 'high' 2 3 1 clk_only = 'high' register programmed 2 xto_rdy = 'high' clk_only = 'high' register programmed 2 clk_only = 'low' register programmed 2 )"register partly programmed": negative sck edge of 32-bit register programming msb-1 (s433_n315) to transition from one state to another, only the conditions next to the transition arrows must be fulfilled. no additional settings are required. ) "pll locked" 1280 xto cycles (t pll ) after register programmed and xto_rdy = 'high' ) "register programmed'" negative sck edge of 32-bit register programming lsb (clk_on) ask_nfsk = 'high' and sdin_txdin = 'low' ask_nfsk = 'low' or (ask_nfsk = 'high' and sdin_txdin = 'high') pll locked 3 en = 'high' sdin_txdin = 'low' en = 'high' sdin_txdin = 'low' en = 'low' sdin_txdin = 'low' en = 'low' sdin_txdin = 'low' en = 'low' sdin_txdin = 'low' en = 'low' sdin_txdin = 'high' en = 'low' sdin_txdin = 'high' en = 'low' sdin_txdin = 'high' en = 'low' sdin_txdin = 'low' tx_mode_1 clock_only_mode start-up_mode_1 off_mode configuration_mode_1 configuration_mode_2 reset_register_mode tx_mode_2 17 ata5749/ata5749c [datasheet] 9128i?rke?04/14 7. esd protection circuit figure 7-1. esd protection circuit clk gnd vs sck sdin_txdin en ant2 ant1 xto2 xto1 8. absolute maximum ratings stresses beyond those listed under ?absolute maximum ratings? may cause permanent damage to the device. this is a stress rating only and functional operation of the device at these or any other conditions beyond t hose indicated in the operational sections of this specification is not implied. exposure to absolute maximum rating conditions for extended periods may affect device reliability . parameters symbol min. max. unit supply voltage v s ?0.3 +4.0 v power dissipation p tot 100 mw junction temperature t j 150 c storage temperature t stg ?55 +125 c ambient temperature ta m b 1 ?40 +125 c ambient temperature in power-down mode for 30 minutes without damage with v s 3.2v, v enable <0.25v or enable is open, v ask < 0.25v, v fsk <0.25v ta m b 2 175 c esd (human body model esd s5.1) every pin excluding pin 5 (ant1) hbm ?4 +4 kv esd (human body model esd s5.1) for pin 5 (ant1) hbm ?2 +2 kv esd (machine model jedec a115a) every pin excluding pin 5 (ant1) mm ?200 +200 v esd (machine model jedec a115a) for pin 5 (ant1) mm ?150 +150 v esd ? stm 5.3.1-1999 every pin cdm 750 v 9. thermal resistance parameters symbol value unit thermal resistance, junction ambient r thja 170 k/w ata5749/ata5749c [datasheet] 9128i?rke?04/14 18 10. electrical characteristics v s = 1.9v to 3.6v t amb = ?40c to +125c, clk_on = ?high?; div_cntrl = ?low?, cload_clk = 10pf. f xto = 13.0000mhz, f clk = 1.625mhz unless otherwise spec ified. if crystal parameters are importan t values correspond to a crystal with c m = 4.0ff, c 0 = 1.5pf, c load = 9pf and r m 170 . typical values are given at v s = 3.0v and t amb = 25c no. parameters test conditions pin symbol min. typ. max. unit type* 1 current consumption 1.1 supply current, off_mode v(sdin_txdin,sck,en) = low t amb +25c t amb +85c t amb +125c 5, 8 i s_off_mode 1 20 265 100 350 7,000 na na na a 1.2 supply current, tx_mode1 v s 3.0v 5, 8 i s_tx_mode1 3.6 4.75 ma b 1.3 supply current, tx_mode2 v s 3.0v pwr[0:3] = 8 (5.5dbm) 5, 8 i s_tx_mode2 7.3 8.8 ma b 1.4 supply current, clk_only_mode v s 3.0v 5, 8 i s_clk_only _ mode 480 680 a b 1.5 supply current reduction, clock driver off v s 3.0v clk_on = ?low? i s = i s_any_mode + i clkoff1 (can be applied to all modes except off_mode, add typ. to typ. and max. to max. values) 5, 8 i clkoff1 ?250 ?300 a b 1.6 supply current increase, clock driver higher frequency v s 3.0v div_cntrl = ?high? f clk =3.24mhz i s = i s_any__mode + i clkhigh (can be applied to all modes except off_mode add typ. to typ. and max. to max. values) 5, 8 i clkhigh 150 190 a b 1.7 reset_register_mode / configuration_mode_1 v s 3.0v 5, 8 i s_reset_ register_mode / i s_configuration _ mode_1 680 a b 1.8 configuration_mode_2 / start_up_mode_2 v s 3.0v 5, 8 i s_configuration _mode_2 / i s_start_up _mode_2 4.75 ma b 1.9 start_up_mode_1 v s 3.0v 5, 8 i s_start_up _mode_1 350 a b 2 power amplifier (pa) 2.1 output power 1, tx_mode2 v s = 3.0v, t amb = 25c pwr[0:3] = 4 z load = z lopt according to table 4-1 on page 9 and table 4-2 on page 9 (5) p out_1 ?1.0 +1.0 +3.0 dbm b *) type means: a = 100% tested, b = 100% correlation test ed, c = characterized on samples, d = design parameter note: (pin number) in brackets mean they are measured matched to 50 according to figure 4-2 on page 8 with component values and optimum load impedances according to table 4-1 and table 4-2 on page 9 19 ata5749/ata5749c [datasheet] 9128i?rke?04/14 2.2 supply current 1, tx_mode2 v s = 3.0v pwr[0:3] = 4 5, 8 i s_p1 5.4 6.7 ma b v s = 3.6v pwr[0:3] = 4 5, 8 i s_p1 7.0 ma a 2.3 output power 2, tx_mode2 v s = 3.0v, t amb = 25c pwr[0:3] = 8 z load = z lopt according to table 4-1 on page 9 and table 4-2 on page 9 (5) p out_2 4.0 5.5 7.0 dbm a 2.4 supply current 2, tx_mode2 v s = 3.0v, pwr[0:3] = 8 [typ. 5.5dbm; see 2.3] 5, 8 i s_p2 7.3 8.8 ma b v s = 3.6v, pwr[0:3] = 8 [typ. 5.5dbm; see 2.3] 5, 8 i s_p2 9.1 ma a 2.5 output power 3, tx_mode2 v s = 3.0v, t amb = 25c pwr[0:3] = 15 z load = z lopt according to table 4-1 on page 9 and table 4-2 on page 9 (5) p out_3 11.0 12.5 14.0 dbm b 2.6 supply current 3, tx_mode2 v s = 3.0v pwr[0:3] = 15 5, 8 i s_p3 20.2 23.5 ma a v s = 3.6v pwr[0:3] = 15 5, 8 i s_p3 24.5 ma a 2.7 output power variation for full temperature and supply voltage range t amb = ?40c to +125c v s = 1.9v to 3.6v pout = p out_x + p out (can be applied to all power levels) (5) p out ?4.0 +1.5 db b 3 crystal oscillator (xto) 3.1 maximum series resistance r m of xtal after start-up c 0 < 2.0pf 6, 7 r m_max 170 d 3.2 motional capacitance of xtal recommended values 6, 7 c m 2 4.0 15 ff d 3.3 stabilized amplitude xtal c 0 < 2.0pf c m = 4.0ff r m = 20 c load = 9pf v(xto2) ? v(xto1) v(xto1) 6, 7 vpp xto21 vpp xto1 640 320 mvpp a 3.4 pulling of f xto versus temperature and supply change 1.0 < c 0 < 2.0pf r m < 170 c load = 9pf 4ff < c m < 10ff c m < 15ff 6, 7 f rf ?3 ?5 +3 +5 ppm c 10. electrical characteristics (continued) v s = 1.9v to 3.6v t amb = ?40c to +125c, clk_on = ?high?; div_cntrl = ?low?, cload_clk = 10pf. f xto = 13.0000mhz, f clk = 1.625mhz unless otherwise spec ified. if crystal parameters are importan t values correspond to a crystal with c m = 4.0ff, c 0 = 1.5pf, c load = 9pf and r m 170 . typical values are given at v s = 3.0v and t amb = 25c no. parameters test conditions pin symbol min. typ. max. unit type* *) type means: a = 100% tested, b = 100% correlation test ed, c = characterized on samples, d = design parameter note: (pin number) in brackets mean they are measured matched to 50 according to figure 4-2 on page 8 with component values and optimum load impedances according to table 4-1 and table 4-2 on page 9 ata5749/ata5749c [datasheet] 9128i?rke?04/14 20 3.5 dc voltage after xtal amplitude stable v(xto2) ? v(xto1) xto running 6, 7 v dc_xto 40 mv c 3.6 negative real part of xto impedance at begin of start-up this value is important for crystal oscillator start-up behavior c 0 < 2.0pf, 8pf < c load < 10pf f xtal = 13.000mhz 11.0mhz < f xtal <14.8mhz 6, 7 r xto12_start ?1,500 ?1,300 ?2,200 b 3.7 external capacitors c4, c5 recommended values for proper start-up and low current consumption quality npo c load = (c 4 + c xto1 ) (c 5 + c xto2 ) / (c 4 + c 5 + c xto1 + c xto2 ) c load_nom = 9pf (inc. pcb) 6, 7 c 4 c 5 ?5% 15 +5% pf d 3.8 pin capacitance xto1 and xto2 the pcb capacitance of about 1pf has to be added 6, 7 c xto1 c xto2 ?15% ?15% 2 2 +15% +15% pf c 3.9 crystal oscillator start- up time time between en = ?high? and xto_rdy = ?high? c 0 < 2.0pf, 4ff < c m < 15ff c 0 < 2.0pf, 2ff < c m < 15ff r m < 170 11.0mhz < f xtal < 14.8mhz 6, 7, 1 t xto 0.20 0.32 0.3 0.5 ms b 3.10 maximum shunt capacitance c 0 of xtal required for stable operation of xto, c load > 7. 5pf 6, 7 c 0_max 1.5 3.0 pf d 3.11 oscillator frequency xto 433.92mhz and 315mhz other frequencies 6, 7 f xto 11.0 13.0000 14.8 mhz c 4 fractional-n-pll 4.1 frequency range of rf frequency s434_n315 = ?low? s434_n315 = ?high? 5 f rf 300 367 368 450 mhz a 4.2 locking time of the pll time between xto_rdy= ?high? and register programmed till pll is locked f xto = 13.0000mhz other f xto 1, 5 t pll 98.46 s b 4.3 pll loop bandwidth unity gain loop frequency of synthesizer 5 f loop_pll 140 280 380 khz b 4.4 in loop phase noise pll 25khz distance to carrier 5 l pll ?83 ?76 dbc/hz a 4.5 out of loop phase noise (vco) at 1mhz at 36mhz 5 l at1m l at36m ?91 ?122 ?84 ?115 dbc/hz dbc/hz a c 4.6 fsk modulation frequency duty cycle of the modulation signal = 50%, (this corresponds to 40kbit/s manchester coding and 80kbit/s nrz coding) 2, 5 f mod_fsk 0 40 khz b 10. electrical characteristics (continued) v s = 1.9v to 3.6v t amb = ?40c to +125c, clk_on = ?high?; div_cntrl = ?low?, cload_clk = 10pf. f xto = 13.0000mhz, f clk = 1.625mhz unless otherwise spec ified. if crystal parameters are importan t values correspond to a crystal with c m = 4.0ff, c 0 = 1.5pf, c load = 9pf and r m 170 . typical values are given at v s = 3.0v and t amb = 25c no. parameters test conditions pin symbol min. typ. max. unit type* *) type means: a = 100% tested, b = 100% correlation test ed, c = characterized on samples, d = design parameter note: (pin number) in brackets mean they are measured matched to 50 according to figure 4-2 on page 8 with component values and optimum load impedances according to table 4-1 and table 4-2 on page 9 1280/ f xto ?? ?? 21 ata5749/ata5749c [datasheet] 9128i?rke?04/14 4.7 ask modulation frequency duty cycle of the modulation signal = 50%, (this corresponds to 40kbit/s manchester coding and 80kbit/s nrz coding) 2, 5 f mod_ask 0 40 khz b 4.8 spurious emission at f rf f xto / 8 at f rf f xto / 4 at f rf f xto 5 spur ?47 ?47 ?60 dbc b 4.9 spurious emission div_cntrl = ?high? at f rf f xto / 4 at f rf f xto 5 spur ?47 ?58 dbc b 4.10 spurious emission clk_on = ?low? at f 0 f xto 5 spur ?60 dbc b 4.11 fractional spurious ask_nfsk = ?high? tx_mode_2 freq[0:14] = 3730, fsep[0:7] = 101 s434_n315 = ?low? f rf 3.00mhz f rf 6.00mhz freq[0:14] = 14342, fsep[0:7] = 101 s434_n315 = ?high? f rf 3.159mhz f rf 9.840mhz 5 spur ?50 ?50 ?50 ?50 dbc b 4.12 fsk frequency deviation f xto = 13.0000mhz other f xto see table 3-1 on page 4 5 f dev 0.396 101.16 khz a 4.13 frequency resolution f xto = 13.0000mhz other f xto f pll 793 hz a 10. electrical characteristics (continued) v s = 1.9v to 3.6v t amb = ?40c to +125c, clk_on = ?high?; div_cntrl = ?low?, cload_clk = 10pf. f xto = 13.0000mhz, f clk = 1.625mhz unless otherwise spec ified. if crystal parameters are importan t values correspond to a crystal with c m = 4.0ff, c 0 = 1.5pf, c load = 9pf and r m 170 . typical values are given at v s = 3.0v and t amb = 25c no. parameters test conditions pin symbol min. typ. max. unit type* *) type means: a = 100% tested, b = 100% correlation test ed, c = characterized on samples, d = design parameter note: (pin number) in brackets mean they are measured matched to 50 according to figure 4-2 on page 8 with component values and optimum load impedances according to table 4-1 and table 4-2 on page 9 f xto / 32768 ?? ?? f xto / 128.5 ?? ?? f xto / 16384 ?? ?? ata5749/ata5749c [datasheet] 9128i?rke?04/14 22 11. timing characteristics (atmel ata5749) v s = 1.9v to 3.6v, t amb = ?40c to +125c. typical values are given at v s = 3.0v and t amb = 25c. all parameters are referred to gnd (pin 9). parameters where crystal relevant parameters are important correspond to a crystal with c m = 4.0ff, c 0 = 1.5pf, c load =9pf and r m 170 unless otherwise specified. no. parameters test conditions pin symbol min. typ. max. unit type* 1.1 en set-up time to rising edge of sck 1, 10 t en_setup 10 s c 1.2 sdin_txdin set-up time to falling edge of en 2, 10 t sdin_txdin _setup 125 ns c 1.3 sdin_txdin set-up time to rising edge of sck 2, 3 t setup 10 ns c 1.4 sdin_txdin hold time from rising edge of sck 2, 3 t hold 10 ns c 1.5 sck cycle time 3 t sck_cycle 500 ns c 1.6 sck high time period 3 t sck_high 200 ns c 1.7 sck low time period 3 t sck_low 200 ns c 1.8 en low time period with sdin_txdin = ?high? for register reset 2, 10 t en_reset 10 us c 1.9 clock output frequency (cmos microcontroller compatible) f xto = 13.000mhz div_cntrl = ?high? (f clk = f xto / 4) div_cntrl = ?low? (f clk = f xto / 8) 1 f clk 3.25 1.625 mhz a 1.10 clock output minimum ?high? and ?low? time cload 20pf, div_cntrl = ?low? (f clk =f xto / 8) ?high? = 0.8 v s , ?low? = 0.2 v s , f clk < 1.625mhz 1 t clklh 125 220 ns a 1.11 clock output minimum ?high? and ?low? time cload 10pf, div_cntrl = ?high? (f clk = f xto / 4) ?high? = 0.8 v s , ?low? = 0.2 v s , f clk < 3.25mhz 1 t clklh 62.5 110 ns a 1.12 clock output minimum ?high? and ?low? time cload 20pf, div_cntrl = ?low? (f clk = f xto / 8) ?high? = 0.8 v s , ?low? = 0.2 v s , f clk < 1.85mhz 1 t clklh 125 180 ns c 1.13 clock output minimum ?high? and ?low? time cload 10pf, div_cntrl = ?high? (f clk = f xto / 4) ?high? = 0.8 v s , ?low? = 0.2 v s , f clk < 3.7mhz 1 t clklh 62.6 90 ns c *) type means: a = 100% tested, b = 100% correlation test ed, c = characterized on samp les, d = design parameter 23 ata5749/ata5749c [datasheet] 9128i?rke?04/14 12. digital port characteristics v s = 1.9v to 3.6v, t amb = 40c to +125c unless otherwise specif ied. typical values are given at v s = 3.0v and t amb = 25c, all inputs are schmitt trigger interfaces. no. parameters test conditions pin symbol min. typ. max. unit type* 1.1 sdin_txdin ?low? level input voltage ?high? level input voltage internal pull-down resistor v ii v ih r pdn 0 v s ?0.25 160 250 0.25 v s 380 v v k a 1.2 sck ?low? level input voltage ?high? level input voltage internal pull-down resistor v ii v ih r pdn 0 v s ?0.25 160 250 0.25 v s 380 v v k a 1.3 en input ?low? level input voltage ?high? level input voltage internal pull-down resistor v ii v ih r pdn 0 v s ?0.25 160 250 0.23 v s 380 v v k a *) type means: a = 100% tested, b = 100% correlation test ed, c = characterized on samp les, d = design parameter ata5749/ata5749c [datasheet] 9128i?rke?04/14 24 14. package information 13. ordering information extended type number package remarks ata5749-6dqy tssop10 - ata5749c-6dqy tssop10 - package drawing contact: packagedrawings@atmel.com gpc drawing no. rev. title 6.543-5095.01-4 3 09/16/05 package: tssop (acc. to jedec standard mo-187) not indicated tolerances 0.05 dimensions in mm specifications according to din technical drawings 0.5 nom. 0.25 1345 2 10 8 7 6 9 0.15 4 x 0.5 = 2 nom. 1.1 max 0.85 0.1 3 0.1 3.8 0.3 4.9 0.1 3 0.1 25 ata5749/ata5749c [datasheet] 9128i?rke?04/14 15. revision history please note that the following page numbers re ferred to in this section re fer to the specific revision mentioned, not to this document. revision no. history 9128i-rke-04/14 ? put datasheet in the latest template 9128h-rke-08/11 ? section 13 ?ordering information? on page 24 changed 9128g-rke-03/11 ? ata5749c on page 1 added ? section 13 ?ordering information? on page 24 changed 9128f-rke-09/10 ? page 9: table 4-1 changed ? page 9: table 4-2 changed 9128e-rke-09/10 ? el. char. table: rows 1.2, 1.3, 1.4, 1. 7, 1.8, 1.9, 2.1, 2.2, 2.4, 2.5 changed ? dig. port char. table: row 1.3 changed ? ordering table changed 9128d-rke-01/09 ? features on page 1 changed ? section 8 ?absolute maximum ratings? on page 17 changed 9128c-rke-10/08 ? features on page 1 changed ? section 8 ?absolute maximum ratings? on page 17 changed ? section 12 ?digital port characteristics? on page 23 changed 9128b-rke-08/08 ? put datasheet in the newest template ? features on page 1 changed ? section 1 ?description? on page 1 changed ? figure 1-1 ?block diagram? on page 2 changed ? section 3.1 ?fractional-n pll? on page 4 changed ? section 3.4 ?clock driver? on page 6 changed ? figure 4-1 ?typical application circuit? on page 7 changed ? figure 4-2 ?output power measurement circuit? on page 8 changed ? section 10 ?electrical characteristics? nu mbers 4.2, 4.12 and 4.13 on pages 20 to 21 changed x x xx x x atmel corporation 1600 technology drive, san jose, ca 95110 usa t: (+1)(408) 441.0311 f: (+1)(408) 436.4200 | www.atmel.com ? 2014 atmel corporation. / rev.: rev.: 9128i?rke?04/14 atmel ? , atmel logo and combinations thereof, enabling unlimited possibilities ? , and others are registered trademarks or trademarks of atmel corporation or its subsidiaries. other terms and product names may be trademarks of others. disclaimer: the information in this document is provided in c onnection with atmel products. no license, express or implied, by estoppel or otherwise, to any intellectual property right is granted by this document or in connection with the sale of atmel products. except as set forth in the atmel terms and condit ions of sales located on the atmel website, atmel assumes no liability wh atsoever and disclaims any express, implied or statutory warranty relating to its p roducts including, but not limited to, the implied warranty of merchantability, fitness for a particular purpose, or non-infringement. in no event shall atmel be liable for any direct, indirect, consequential, pu nitive, special or incidental damages (including, without limi tation, damages for loss and profits, business interruption, or loss of information ) arising out of the use or inability to use this document, even if atmel has been advised of the possibility of such damages. atmel makes no r epresentations or warranties with respect to the accuracy or c ompleteness of the contents of this document and reserves the right to make changes to specificatio ns and products descriptions at any time without notice. atmel d oes not make any commitment to update the information contained herein. unless specifically provided otherwise, atme l products are not suitable for, and shall not be used in, automo tive applications. atmel products are not intended, authorized, or warranted for use as components in applications intended to support or sustain life. safety-critical, military, and automotive applications disclaim er: atmel products are not designed for and will not be used in connection with any applications where the failure of such products would reasonably be expected to re sult in significant personal inju ry or death (?safety-critical a pplications?) without an atmel officer's specific written consent. safety-critical applications incl ude, without limitation, life support devices and systems, equipment or systems for t he operation of nuclear facilities and weapons systems. atmel products are not designed nor intended for use in military or aerospace applications or environments unless specifically designated by atmel as military-grade. atmel products are not designed nor intended for use in automot ive applications unless spec ifically designated by atmel as automotive-grade. |
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