View GRM155R71C104K_8320054.PDF datasheet online --- IC-ON-LINE

Datasheet File OCR Text:

f1423 datasheet tx differential input rf amplifier 600 mhz to 3000 mhz f1423, rev o 11/6/2015 1 ? 2015 integrated device technology, inc. g eneral d escription the f1423 is a 600 mhz to 3000 mhz tx differential input / singleended output rf amplifier used in transmitter applications. the f1423 tx amp provides 13.1 db gain with +41.8 dbm oip3 and 5.1 db noise figure at 2000 mhz. this device uses a single 5 v supply and 120 ma of i cc . this device is packaged in a 4mm x 4mm, 24pin thin qfn with 50 ohm differential rf input and 50 ohm single ended rf output impedances for ease of integration into the signalpath. c ompetitive a dvantage in typical base stations, rf amplifiers are used in the tx traffic paths to drive the transmit power amplif ier. the f1423 tx amplifier offers very high reliability due to its construction using silicon die in a qfn pack age. the f1423 includes a broadband differential input t o accept accoupled signals directly from a balanced modulator or rf dac architecture. a pplications ? multimode, multicarrier transmitters ? gsm850/900 base stations ? pcs1900 base stations ? dcs1800 base stations ? wimax and lte base stations ? umts/wcdma 3g base stations ? phs/pas base stations ? public safety infrastructure f eatures ? broadband 600 mhz C 3000 mhz ? 13.1 db typical gain @ 2000 mhz ? 5.1 db nf @ 2000 mhz ? +41.8 dbm oip3 @ 2000 mhz ? +21.5 dbm output p1db @ 2000 mhz ? single 5 v supply voltage ? i cc = 120 ma ? up to +105 c t case operating temperature ? 50 differential input impedance ? 50 single ended output impedance ? positive gain slope for board loss compensation ? standby mode for power savings ? 4 mm x 4 mm, 24pin tqfn package f unctional b lock d iagram rfout rfin stby band sel o rdering i nformation f1423nbgi8 green tape & reel rf p roduct line
f1423 zero-distortion tm , tx amplifier 2 rev o 11/6/2015 a bsolute m aximum r atings parameter symbol min max units v cc to gnd v cc 0.3 +5.5 v stby, band_sel v cntl 0.3 v cc + 0.25 v rbias1 i rb1 +1.5 ma rbias2 i rb2 +0.8 ma rfin+, rfin, voltage 1 v rfin 0.02 +0.02 v rfin+, rfin, current 1 i rfin 5 +5 ma rfout externally applied dc voltage v rfout v cc 0.15 v cc + 0.15 v rf differential input power (applied for 24 hours maximum) p in +22 dbm continuous power dissipation p diss 1.5 w junction temperature t j 150 c storage temperature range t st 65 150 c lead temperature (soldering, 10s) 260 c electrostatic discharge C hbm (jedec/esda js0012014) class 2 (2000 v) electrostatic discharge C cdm (jesd 22c101f) class c3 (1000 v) note 1: the rfin+ and rfin pins connect to an inte rnal balun that presents a very low impedance to gr ound. stresses above those listed above may cause permane nt damage to the device. functional operation of th e device at these or any other conditions above those indicated in the operational section of this specification i s not implied. exposure to absolute maximum rating conditions for extended periods may affect device reliability. p ackage t hermal and m oisture c haracteristics ja (junction C ambient) 40 c/w jc (junction C case) [the case is defined as the expos ed paddle] 4 c/w moisture sensitivity rating (per jstd020) msl1
f1423 rev o 11/6/2015 3 zero-distortion tm , tx amplifier f1423 r ecommended o perating c onditions parameter symbol conditions min typ max units supply voltage(s) v cc all v cc pins 4.75 5.25 v operating temperature range t case case temperature 40 +105 c rf frequency range f rf operating range 600 3000 1 mhz rf source impedance z rfi differential 50 rf load impedance z rfo single ended 50 rf band designation 2 rf frequency range f rf_lb lowband 600 1100 mhz f rf_mb midband 1400 2100 f rf_hb highband 2100 3000 1 f rf_bb broadband 600 3000 1 note 1: though device linearity is specified over t he range from 700 mhz to 2700 mhz, gain flatness up to 3000 mhz is specified in the highband and broadband tables to account for extended dpd bandwidth requirements . note 2: to optimize rf performance, a different out put match will be used for each of the 4 rf bands l isted (see table 2). in addition, different value amplifier b ias resistors will be used to optimize performance in each of the 4 bands.
f1423 zero-distortion tm , tx amplifier 4 rev o 11/6/2015 f1423 s pecification - g eneral see f1423 typical application circuit. unless other wise stated, specifications apply when operated as a tx rf amplifier, v cc = +5.0 v, t c = +25 c. parameter symbol condition min typ max units logic input high v ih 1.1 v logic input low v il 0.63 logic current i stby stby pin -10 +10 a i band band_sel pin -10 +10 supply current 3 i cc_lb lowband bias setting 103 ma i cc_mb midband bias setting 120 i cc_hb highband bias setting 120 i cc_bb broadband bias setting 120 135 1 standby current i cc_stby stby = 5v 0.8 1.0 ma power on switching time t on 50% stby to rf output settled to within 0.5db 1 s power off switching time t off 50% stby to dc standby current settled to within 2ma of final i cc value 1 s note 1: items in min/max columns in bold italics are guaranteed by test. note 2: items in min/max columns that are not bold/ italics are guaranteed by design characterization. note 3: use external resistors to set amplifier bia s currents to optimize device linearity. see table 2.
f1423 rev o 11/6/2015 5 zero-distortion tm , tx amplifier f1423 s pecification C l ow -b and see f1423 typical application circuit. unless other wise stated, specifications apply when operated as a tx rf amplifier, v cc = +5.0 v, t c = +25 c, f rf = 700 mhz, pout = +7 dbm, r8 =2.1 k?, r9 =9.1 k?, c1 = 9 pf, rsource = 50 ? differential, rload = 50 ? singleen ded, band_sel = open, evkit trace connector and tra nsformer losses are deembedded. parameter symbol condition min typ max units rf input return loss rfin rl_lb 17 db rf output return loss rfout rl_lb 12.8 db common mode rejection cmrr lb 700 mhz to 1100 mhz 20.7 db gain g lb 12.0 1 12.6 13.2 db gain flatness g flat_lb any 400 mhz bw from 700 mhz to 1100 mhz 0.4 db gain ripple g ripple_lb in any 20 mhz range over rf band 0.04 db noise figure 3 nf lb 4.5 db t case = +105 c 5.4 output third order intercept point 3 oip3 lb pout = +4 dbm/tone 5 mhz tone separation 39 2 42.5 dbm output 1db compression 3 op1db lb 20 21.1 dbm f1423 s pecification C m id -b and see f1423 typical application circuit unless otherw ise stated, specifications apply when operated as a tx rf amplifier, v cc = +5.0 v, t c = +25 c, f rf = 2000 mhz, pout = +7 dbm, r8 =2.4 k?, r9 =60.4 k? , c1 = 9 pf, rsource = 50 ? differential, rload = 50 ? singleen ded, band_sel = gnd, evkit trace connector and tran sformer losses are deembedded. parameter symbol condition min typ max units rf input return loss rfin rl_mb 15 db rf output return loss rfout rl_mb 16.5 db common mode rejection cmrr mb 1400 mhz to 2100 mhz 19.0 db gain g mb 12.5 1 13.1 13.7 db gain flatness g flat_mb any 400mhz bw from 1400 mhz to 2100 mhz 0.17 db gain ripple g ripple_mb in any 20 mhz range over rf band 0.01 db noise figure 3 nf mb 5.1 db t case = +105 c 5.8 output third order intercept point 3 oip3 mb pout = +4 dbm/tone 5mhz tone separation 38.8 2 41.8 dbm output 1db compression 3 op1db mb 20.3 21.5 dbm note 1: items in min/max columns in bold italics are guaranteed by test. note 2: items in min/max columns that are not bold/ italics are guaranteed by design characterization. note 3: measured using external 1:1 transformer at the rf input.
f1423 zero-distortion tm , tx amplifier 6 rev o 11/6/2015 f1423 specification C high-band see f1423 typical application circuit. unless other wise stated, specifications apply when operated as a tx rf amplifier, v cc = +5.0 v, t c = +25 c, f rf = 2700 mhz, pout = +7 dbm, r8 =2.4 k?, r9 =60.4 k? , c1 = 6 pf, rsource = 50 ? differential, rload = 50 ? singleen ded, band_sel = gnd, evkit trace connector and tran sformer losses are deembedded. parameter symbol condition min typ max units rf input return loss rfin rl_hb 15.5 db rf output return loss rfout rl_hb 20 db common mode rejection cmrr hb 2100 mhz to 3000 mhz 18.5 db gain g hb 12.4 1 13.1 13.9 db gain flatness g flat_hb any 400 mhz bw from 2100 mhz to 3000 mhz 0.23 db gain ripple g ripple_hb in any 20 mhz range over rf band 0.015 db noise figure 3 nf hb 6.0 db t case = +105 c 6.6 output third order intercept point 3 oip3 hb pout = +4 dbm/tone 5mhz tone separation 37.3 dbm output 1db compression 3 op1db hb 20.0 2 20.6 dbm f1423 specification C broad-band see f1423 typical application circuit. unless other wise stated, specifications apply when operated as a tx rf amplifier, v cc = +5.0 v, t c = +25 c, f rf = 2200 mhz, pout = +7 dbm, r8 =2.4 k?, r9 =60.4 k? , c1 = 9 pf, rsource = 50 ? differential, rload = 50 ? singleen ded, band_sel = gnd, evkit trace connector and transformer losses are deembedded. parameter symbol condition min typ max units rf input return loss rfin rl_bb 15.0 db rf output return loss rfout rl_bb 18.5 db common mode rejection cmrr bb 700 mhz to 3000 mhz 18.5 db gain g bb 12.6 1 13.2 13.8 db gain flatness g flat_bb any 400 mhz bw from 700 mhz to 3000 mhz 0.4 db gain ripple g ripple_bb in any 20 mhz range over 400 mhz bw 0.04 db gain slope g slope_bb 0.002 db/mhz noise figure 3 nf bb 5.2 db t case = +105 c 5.8 output third order intercept point 3 oip3 bb pout = +4 dbm/tone 5 mhz tone separation 41.4 dbm output 1db compression 3 op1db bb 20.5 2 21.4 dbm note 1: items in min/max columns in bold italics are guaranteed by test. note 2: items in min/max columns that are not bold/ italics are guaranteed by design characterization. note 3: measured using external 1:1 transformer at the rf input.
f1423 rev o 11/6/2015 7 zero-distortion tm , tx amplifier table1: stby truth table parameter level function stby logic low or open circuit powered on logic high powered off table2: component settings for optimized linearity performa nce per rf band band frequency range (mhz) band_sel (pin 11) pin 14 to gnd (k ?) pin 15 to gnd (k ?) c1 (pf) i cc (ma) low band 600 1100 open 2.1 9.1 9 104 mid band 1400 2100 gnd 2.4 60.4 9 120 high band 2100 3000 gnd 2.4 60.4 6 120 broad band 700 3000 gnd 2.4 60.4 9 120 t ypical o perating c onditions (toc) unless otherwise noted for the toc graphs on the fo llowing pages, the following conditions apply. ? vcc= 5.0 v ? tcase = 25 c (all temperatures are referenced to the exposed pa ddle). ? z s = 50 ohms differential ? z l = 50 ohms single ended ? board configured as defined in table 2 for each band . ? pout = 4 dbm / tone ? 5 mhz tone spacing ? evkit traces, connectors, and transformer losses ar e de-embedded. ? s-parameters (s11, s21, s12, and s22) measured using a de-embedded differential board evkit and the inputs are mathematically combined using an ideal 1 :1 (50 : 50 ) transformer to produce the 2 port s-parameters. ? amplitude and phase imbalances measures rfin+ to rfout and compares to rfin- to rfout. phase imbalance is the deviation from an ideal 180 degre es. ? oip3, output p1db and noise figure measured using a t ransformer board evkit. note: the use of the external transformer t1 is in cluded for simple 2 port evaluation purposes. at some frequencies the external transformer i nteracts with the onchip balun affecting the gain and noise figure flatness responses. these interactions have been removed from the noise figure tocs.
f1423 zero-distortion tm , tx amplifier 8 rev o 11/6/2015 toc s [d ifferential b oard s-p ars , a mplitude and p hase i mbalance , b road -b and b ias ](-1-) rf gain vs. vcc and t case output match vs. vcc and t case amplitude imbalance vs. t case input match vs. vcc and t case reverse gain vs. vcc and t case phase imbalance vs. t case 10 10.5 11 11.5 12 12.5 13 13.5 14 14.5 15 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -30 -25 -20 -15 -10 -5 0 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 output match (db) frequency (ghz) 4.75v, - 40c 5.00v, - 40c 5.25v, - 40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -1.5 -1 -0.5 0 0.5 1 1.5 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 amplitude imbalance (db) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm -40 -35 -30 -25 -20 -15 -10 -5 0 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 input match (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -28 -26 -24 -22 -20 -18 -16 -14 -12 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 reverse gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -20 -15 -10 -5 0 5 10 15 20 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 phase imbalance (deg) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm
f1423 rev o 11/6/2015 9 zero-distortion tm , tx amplifier toc s [t ransformer b oard , oip3, p1db, n oise f igure , i cc , b road -b and b ias ](-2-) oip3 vs. vcc and t case output p1db vs. vcc and t case icc vs. vcc and t case oip3 vs. pout level noise figure vs. vcc and t case 10 15 20 25 30 35 40 45 50 55 60 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 oip3 (dbm) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 18 19 20 21 22 23 24 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 op1db (dbm) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 100 105 110 115 120 125 130 135 140 4.75 5 5.25 icc (ma) vcc (volts) - 40c 25c 105c 10 15 20 25 30 35 40 45 50 55 60 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 oip3 (dbm) frequency (ghz) 0dbm/tone 2dbm/tone 4dbm/tone 4 4.5 5 5.5 6 6.5 7 7.5 8 0.6 0.9 1.2 1.5 1.8 2.1 2.4 2.7 3 noise figure (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c
f1423 zero-distortion tm , tx amplifier 10 rev o 11/6/2015 toc s [d ifferential b oard s-p ars , a mplitude and p hase i mbalance , l ow -b and b ias ](-3-) rf gain vs. vcc and t case output match vs. vcc and t case amplitude imbalance vs. t case input match vs. vcc and t case reverse gain vs. vcc and t case phase imbalance vs. t case 10 10.5 11 11.5 12 12.5 13 13.5 14 14.5 15 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -30 -25 -20 -15 -10 -5 0 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 output match (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -1.5 -1 -0.5 0 0.5 1 1.5 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 amplitude imbalance (db) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm -40 -35 -30 -25 -20 -15 -10 -5 0 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 input match (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -28 -26 -24 -22 -20 -18 -16 -14 -12 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 reverse gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -20 -15 -10 -5 0 5 10 15 20 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 phase imbalance (deg) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm
f1423 rev o 11/6/2015 11 zero-distortion tm , tx amplifier toc s [t ransformer b oard , oip3, p1db, n oise f igure , i cc , l ow -b and b ias ](-4-) oip3 vs. vcc and t case noise figure vs. vcc and t case output p1db vs. vcc and t case icc vs. vcc and t case 10 15 20 25 30 35 40 45 50 55 60 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 oip3 (dbm) frequency (ghz) 4.75v, - 40c 5.00v, - 40c 5.25v, - 40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 3 3.5 4 4.5 5 5.5 6 6.5 7 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 noise figure (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 18 19 20 21 22 23 24 0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 output p1db (dbm) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 85 90 95 100 105 110 115 120 125 4.75 5 5.25 icc (ma) vcc (volts) - 40c 25c 105c
f1423 zero-distortion tm , tx amplifier 12 rev o 11/6/2015 toc s [d ifferential b oard s-p ars , a mplitude and p hase i mbalance , m id -b and b ias ](-5-) rf gain vs. vcc and t case output match vs. vcc and t case amplitude imbalance vs. t case input match vs. vcc and t case reverse gain vs. vcc and t case phase imbalance vs. t case 10.5 11 11.5 12 12.5 13 13.5 14 14.5 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -30 -25 -20 -15 -10 -5 0 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 output match (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -1.5 -1 -0.5 0 0.5 1 1.5 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 amplitude imbalance (db) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm -30 -25 -20 -15 -10 -5 0 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 input match (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -28 -26 -24 -22 -20 -18 -16 -14 -12 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 reverse gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -20 -15 -10 -5 0 5 10 15 20 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 phase imbalance (deg) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm
f1423 rev o 11/6/2015 13 zero-distortion tm , tx amplifier toc s [t ransformer b oard , oip3, p1db, n oise f igure , i cc , m id -b and b ias ](-6-) oip3 vs. vcc and t case noise figure vs. vcc and t case output p1db vs. vcc and t case icc vs. vcc and t case 10 15 20 25 30 35 40 45 50 55 60 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 oip3 (dbm) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 4 4.5 5 5.5 6 6.5 7 7.5 8 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 noise figure (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 18 19 20 21 22 23 24 1.4 1.5 1.6 1.7 1.8 1.9 2 2.1 op1db (dbm) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 100 105 110 115 120 125 130 135 140 4.75 5 5.25 icc (ma) vcc (volts) - 40c 25c 105c
f1423 zero-distortion tm , tx amplifier 14 rev o 11/6/2015 toc s [d ifferential b oard s-p ars , a mplitude and p hase i mbalance , h igh -b and b ias ](-7-) rf gain vs. vcc and t case output match vs. vcc and t case amplitude imbalance vs. t case input match vs. vcc and t case reverse gain vs. vcc and t case phase imbalance vs. t case 10 10.5 11 11.5 12 12.5 13 13.5 14 14.5 15 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -30 -25 -20 -15 -10 -5 0 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 output match (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -1.5 -1 -0.5 0 0.5 1 1.5 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 amplitude imbalance (db) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm -40 -35 -30 -25 -20 -15 -10 -5 0 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 input match (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -28 -26 -24 -22 -20 -18 -16 -14 -12 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 reverse gain (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -20 -15 -10 -5 0 5 10 15 20 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 phase imbalance (deg) frequency (ghz) -40c 25c 105c z s = 25 ohm / port z l = 50 ohm
f1423 rev o 11/6/2015 15 zero-distortion tm , tx amplifier toc s [t ransformer b oard , oip3, p1db, n oise f igure , i cc , aclr, h igh -b and b ias ](-8-) oip3 vs. vcc and t case noise figure vs. vcc and t case wcdma aclr vs. pout (par = 4.3 db) output p1db vs. vcc and t case icc vs. vcc and t case wcdma aclr vs. pout (par = 11.4 db) 10 15 20 25 30 35 40 45 50 55 60 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 oip3 (dbm) frequency (ghz) 4.75v, - 40c 5.00v, - 40c 5.25v, - 40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 4 4.5 5 5.5 6 6.5 7 7.5 8 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 noise figure (db) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c -80 -70 -60 -50 -40 -30 -20 2 3 4 5 6 7 8 9 10 11 12 aclr (dbc) average wcdma p out (dbm) aclr1+ aclr1- aclr2+ aclr2- measurement at 2.7 ghz 1 dpch, par = 4.3 db specified pout = 7 dbm 18 19 20 21 22 23 24 2 2.1 2.2 2.3 2.4 2.5 2.6 2.7 2.8 2.9 3 op1db (dbm) frequency (ghz) 4.75v, -40c 5.00v, -40c 5.25v, -40c 4.75v, 25c 5.00v, 25c 5.25v, 25c 4.75v, 105c 5.00v, 105c 5.25v, 105c 100 105 110 115 120 125 130 135 140 4.75 5 5.25 icc (ma) vcc (volts) - 40c 25c 105c -80 -70 -60 -50 -40 -30 -20 2 3 4 5 6 7 8 9 10 11 12 aclr (dbc) average wcdma p out (dbm) aclr1+ aclr1- aclr2+ aclr2- measurement at 2.7 ghz 64 dpch, par = 11.4 db specified pout = 7 dbm
f1423 zero-distortion tm , tx amplifier 16 rev o 11/6/2015 p ackage d rawing (4 mm x 4 mm 24pin tqfn), nbg24 n ote : t he f1423 uses the p2 exposed paddle dimensions noted below
f1423 rev o 11/6/2015 17 zero-distortion tm , tx amplifier l and p attern d imension land pattern to support 2.6 mm x 2.6 mm exposed paddle version (see version p2 of package drawing)
f1423 zero-distortion tm , tx amplifier 18 rev o 11/6/2015 p in d iagram rfin+ nc 1 4 3 2 5 rfin- gnd stby vcc nc gnd gnd gnd nc control circuit e.p. 6 18 15 16 17 14 13 12 9 10 11 8 7 19 22 21 20 23 24 nc nc band_sel gnd rbias1 rbias2 rfout gnd nc gnd nc nc nc p in d escription pin name function 1 rfin+ differential input +. pin looks like a dc short to ground. must use external dc block if dc is present on rf line. 2, 4, 9, 12, 16, 18, 23 gnd ground these pins. these pins are internally connec ted to the exposed paddle. 3 rfin differential input . pin looks like a dc short to ground. must use external dc block if dc is present on rf line. 5, 6, 7, 8, 19, 20, 21, 22, 24 nc no internal connection. ok to connect to gnd, ok t o connect to vcc. application circuit ties these pins to ground. 10 vcc 5 v power supply. connect to vcc and use bypass ca pacitors as close to the pin as possible. 11 band_sel leave pin open circuited for lowband select and co nnect 0 resistor to gnd for highband select. internally this pin ha s a 1.5 m? pullup resistor that connects to vcc. 13 stby standby (high= device power off, low/open = device power on). internally this pin has a 1 m? pulldown resistor t hat is connected to gnd. 14 rbias1 connect external resistor to gnd. use val ue in table 2. 15 rbias2 connect external resistor to gnd. use val ue in table 2. 17 rfout rf output. must use external dc block as close to the pin as possible. ep exposed pad. internally connected to gnd. solder th is exposed pad to a pcb pad that uses multiple ground vias to prov ide heat transfer out of the device into the pcb ground planes. these multiple ground vias are also required to achieve the noted rf perf ormance.
f1423 rev o 11/6/2015 19 zero-distortion tm , tx amplifier a pplications i nformation the f1423 has been optimized for use in high perfor mance rf applications from 600 mhz to 3000 mhz. stby the stby control pin allows for power saving when t he device is not in use. setting the stby pin to a logic low, or leaving the pin open, will put the device i n normal operation mode. the stby pin has an intern al 1 meg ohm resistor to ground. applying a logic high to this pin will put the part in standby mode. vol tage should not be applied to the stby pin without vcc p resent. band_sel the band_sel control pin can be used to adjust the current in the device for mid band, high band, and wide band frequency applications. this is done by ground ing the band_sel pin. internally there is a 1.5 meg ohm pullup resistor. voltage should not be applied to the band_sel pin without vcc present. rbias1 and rbias2 rbias1 (pin 14) and rbias2 (pin 15) use a single ex ternal resistor to ground on each pin to set the dc current in the device and to optimize the linearity performance of the amplifier stage. the resistor v alues in table 2 can be used as a guide for the rf band of i nterest. by decreasing the resistor value to ground on the rbias1 pin will increase the dc current in the ampl ifier stage. the resistor to ground on rbias2 is us ed to optimize the linearity performance in conjunction w ith the resistor on rbias1. amplifier stability to ensure unconditional stability the value of r1 s hould be set to 510 ohms. this will reduce the rf g ain, oip3, and op1db by approx 0.4 db. additionally, shu nt resistors to ground of approximately 1k ohm shou ld be connected from pin 1 to ground and pin 3 to ground. this will stabilize the circuit due to common mode source impedances. the installed 1k resistor will a dd 0.1 db degradation to the gain and noise figure. the 1k ohm will also dampen any common mode amplitude a nd phase interactions from the differential source impedance and the f1423 differential input impedanc e. power supplies a common vcc power supply should be used for all pi ns requiring dc power. all supply pins should be bypassed with external capacitors to minimize noise and fast transients. supply noise can degrade nois e figure and fast transients can trigger esd clamps and caus e them to fail. supply voltage change or transient s should have a slew rate smaller than 1 v / 20 s. in addit ion, all control pins should remain at 0 v (+/0.3 v) while the supply voltage ramps or while it returns to zero. control pin interface if control signal integrity is a concern and clean signals cannot be guaranteed due to overshoot, unde rshoot, ringing, etc., the following circuit at the input o f each control pin is recommended. this applies to all control pins 11 and 13. note the recommended resistor and c apacitor values do not necessarily match the ev kit bom for the case of poor control signal integrity. 1 4 3 2 5 6 18 15 16 17 14 13 12 9 10 11 8 7 19 22 21 20 23 24 f1423 exposed pad (gnd) 5k ohm stby 2pf 5k ohm 2pf band_sel
f1423 zero-distortion tm , tx amplifier 20 rev o 11/6/2015 evk it p icture (d ifferential b oard ) evk it p icture (t ransformer b oard )
f1423 rev o 11/6/2015 21 zero-distortion tm , tx amplifier evk it / a pplications c ircuit (d ifferential b oard ) evkit / applications circuit (transformer board)
f1423 zero-distortion tm , tx amplifier 22 rev o 11/6/2015 evk it bom (d ifferential b oard ) part ref qty description mfr. part # mfr. c1 1 9.0 pf 0.25 pf, 50 v, c0g, ceramic capacitor (0402) grm1555c1h9r0c murata c2 1 1000 pf 5%, 50 v, c0g, ceramic capacitor (040 2) grm1555c1h102j murata c3 1 0.1 f 10%, 16 v, x7r, ceramic capacitor (040 2) GRM155R71C104K murata c4 1 10 f 20%, 6.3 v, x5r, ceramic capacitor (060 3) grm188r60j106m murata r1 1 not installed (0402) r2, r3, r4 3 0 ? resistor, 1/10w, (0402) erj2ge0r00x panasonic r5, r6 0 not installed r7 1 2.1k 1%, resistor, 1/10w, (0402) erj2rkf210 1x panasonic r8 1 2.4k 1%, resistor, 1/10w, (0402) erj2rkf240 1x panasonic r9 1 60.4k 1%, resistor, 1/10w, (0402) erj2rkf60 42x panasonic r10 1 9.1k 1%, resistor, 1/10w, (0402) erj2rkf91 01x panasonic r11 1 not installed r12 1 not installed j1, j2, j3, j9 4 sma_end_launch (small) 1420711821 emerson johnson j4, j5, j8 3 conn header vert 2 x 1 gold 9611026404 ar 3m j6, j7 2 conn header vert 2 x 4 gold 67997108hlf fci u1 1 rf amplifier f1423nbgi idt 1 printed circuit board (3 port) f1423 evkit (3 po rt)
f1423 rev o 11/6/2015 23 zero-distortion tm , tx amplifier evk it bom (t ransformer b oard ) part ref qty description mfr. part # mfr. c1 1 9.0 pf 0.25 pf, 50 v, c0g, ceramic capacitor (0402) grm1555c1h9r0c murata c2 1 1000 pf 5%, 50 v, c0g, ceramic capacitor (040 2) grm1555c1h102j murata c3 1 0.1 f 10%, 16 v, x7r, ceramic capacitor (040 2) GRM155R71C104K murata c4 1 10 f 20%, 6.3 v, x5r, ceramic capacitor (060 3) grm188r60j106m murata r1 1 not installed (0402) r2, r3, r4 3 0 ? resistor, 1/10w, (0402) erj2ge0r00x panasonic r5, r6 0 not installed r7 1 2.1k 1%, resistor, 1/10w, (0402) erj2rkf210 1x panasonic r8 1 2.4k 1%, resistor, 1/10w, (0402) erj2rkf240 1x panasonic r9 1 60.4k 1%, resistor, 1/10w, (0402) erj2rkf60 42x panasonic r10 1 9.1k 1%, resistor, 1/10w, (0402) erj2rkf91 01x panasonic r11 1 not installed r12 1 not installed r13, r14 2 510 1%, resistor, 1/10w, (0402) (note 1) erj2rkf5100x panasonic t1 1 1:1 wideband transformer tc1143+ mini circuits j1, j3, j9 3 sma_end_launch (small) 1420711821 emerson johnson j4, j5, j8 3 conn header vert 2 x 1 gold 9611026404 ar 3m j6, j7 2 conn header vert 2 x 4 gold 67997108hlf fci u1 1 rf amplifier f1423nbgi idt 1 printed circuit board (transformer) f1423 evkit xfmr note 1: when using an external transformer for eval uation, a common mode resonance interaction can occ ur with the onchip balun. resistors r13 and r14 will dampen th e resonance but affects the gain and nf by approx 0 .2db. t op m arkings idtf14 23nbgi z512acg part number date code [yww] (week 12 of 2015) asm test step assembler code
f1423 zero-distortion tm , tx amplifier 24 rev o 11/6/2015 ev kit o peration the f1423 evkits (single ended and differential) ha ve a number of control features available. stby (2 pin header j5) twopin header j5 can be used to set the part for o perational or standby mode. leaving the two j5 pins unconnected will place it in the operational m ode. connecting the two j5 pins together will pull up the stby pin to vcc through r4 and place the par t into the standby mode. band_sel (2 pin header j4) twopin header j4 can be used to set the part for b est operational performance in different rf bands. based on table 2 above the lowband performance is best with these two j4 pins left open while the other bands typically have these two pins shorted t ogether. rf band biasing (rbias1, rbias2, band_sel) below are 4 settings showing the recommended j4, j7 , and j8 jumper connections for best linearity performance in the different rf bands. the jumpers (shown in red below) select the rbias1 and rbias2 resistor values along with the band_sel sett ing (see table 2 above). never have two shunts installed at the same time on header j7 since this may produce excessive bias current and damage the part. broad-band low-band mid-band high-band
f1423 rev o 11/6/2015 25 zero-distortion tm , tx amplifier r evision h istory s heet rev date page description of change o 2015 nov6 initial release
f1423 zero-distortion tm , tx amplifier 26 rev o 11/6/2015 corporate headquarters 6024 silver creek valley road san jose, ca 95138 usa sales 1-800-345-7015 or 408-284-8200 fax: 408-284-2775 www.idt.com tech support http://www.idt.com/support/technical-support disclaimer integrated device technology, inc. (idt) reserves the right to modify the products and/or sp ecifications described herein at any time, without notice, at idts sole discretion. performance specifications and operating parameters of the described products are determined in an ind ependent state and are not guaranteed to perform th e same way when installed in customer products. the information contained herein is prov ided without representation or warranty of any kind , whether express or implied, including, but not li mited to, the suitability of idts products for any particular purpose, an implied warranty of merc hantability, or noninfringement of the intellectua l property rights of others. this document is pres ented only as a guide and does not convey any license under intellectual property rights of idt o r any third parties. idts products are not intended for use in applicat ions involving extreme environmental conditions or in life support systems or similar devices where th e failure or malfunction of an idt product can be reasonably expected to significantly affect the health or safety of users. anyone using an idt pro duct in such a manner does so at their own risk, ab sent an express, written agreement by idt. integrated device technology, idt and the idt logo are trademarks or registered trademarks of idt and its subsidiaries in the united states and other cou ntries. other trademarks used herein are the property of idt or their respective third party owners. copyright ?2015. integrated device technology, inc. all rights reserved.

▲Up To Search▲

Price & Availability of GRM155R71C104K

	To Download GRM155R71C104K Datasheet File
If you can't view the Datasheet, Please click here to try to view without PDF Reader .