ALM-12224 2.30 GHz – 2.40 GHz 50 Watt High Power SPDT Switch with LNA Module Data Sheet Description Features Avago Technologies’ ALM-12224 is a multi-chip integrated module that comprise of a 50 Watt CW high power SPDT switch, 1st stage low noise amplifier and 2nd stage high gain driver amplifier through the use of Avago Technologies’ proprietary 0.25um GaAs Enhancement-mode pHEMT process and low distortion silicon PIN diode technologies. Very Low Noise Figure The ALM-12224 is housed in a compact 8.0 x 8.0 x 1.2 mm3 molded-chips-on-board (MCOB) module package with 24 pin configuration pads, offering significant PCB space saving as compare to conventional discrete design approach. MSL 2a and Lead-free The device offers high power protection switch (Tx mode operation) with very low insertion loss. During Rx mode operation, the receiver chain provides a very low NF and high gain that makes it an ideal choice for cellular infrastructure in TD-LTE applications. High Power Switch design 50 dB isolation between LNA1_Out and LNA2_In Small package size 8.0 x 8.0 x 1.2 mm3 GaAs E-pHEMT Technology [1] Low Distortion Silicon PIN Diode Technology Specifications Typical Performance at 2.40 GHz (Rx mode) 36.8 dB Gain 0.99 dB Noise Figure 38.5 dBm Output IP3 Typical Performance at 2.40 GHz (Tx mode) Component Image 0.40 dB insertion loss Package Size : 8.0 x 8.0 x 1.2 mm3 Applications Vbias Vc 1 Gnd Gnd Gnd Tx Gnd Pin 1 High power switch LNA module for TD-LTE base station front-end RF application. Gnd AVAGO 12224 WWYY XXXX Gnd Ant Gnd Gnd Block Diagram with Simplified Schematic Gnd Vc1 Vbias Vc 2 Gnd Vg Rx Out Gnd LNA2 Gnd _In External 50 ohm termination Gnd Gnd Gnd LNA1 _Out BOTTOM VIEW Note: Package marking provides orientation and identification “12224” = Device Part Number “WWYY” = Work week and year of manufacture “XXXX” = Last 4 digit of lot number Notes: 1. Enhancement mode technology employs positive Vgs, thereby eliminating the need of negative gate voltage associated with conventional depletion mode devices. C6 C10 Tx Vdd1 TOP VIEW Vdd2 C7 C2 C8 C1 Ant Switch bias circuitry Vc2 PA Vg C9 C5 R1 Vdd1 L1 Rx Out C3 C4 LNA1_Out LNA2_In Absolute Maximum Rating [1] TA = 25° C Symbol Parameter Units Absolute Max. Rx mode Thermal Resistance [2] Vc1,max Device Control Voltage 1 (At Rx mode) V 30 Ic1 ,max Device Control Current 1 (At Rx mode) mA 57 LNA1: Vdd1 = 5.0 V, Idd1 = 50 mA LNA2: Vdd2 = 5.0 V, Idd2 = 120 mA; LNA1 jc = 74.7°C/W LNA2 jc = 69.9°C/W Vc2,max Device Control Voltage 2 (At Tx mode) V 30 Tx mode Thermal Resistance [2] Ic2,max Device Control Current 1 (At Tx mode) mA 57 Vbias Device Bias Voltage V 5.5 Vdd1,2 Device Voltage, RF output to ground V 5.5 Vg Gate Voltage V 0.7 Pin,max Ant CW RF Input Power (Tx mode); 5 mins testing dBm +47.5 Pin,max Ant CW RF Input Power (Rx mode) (Vdd = 5.0 V, Idd1 = 50 mA) dBm +20 Pin,max LNA2_In CW RF Input Power (Vdd = 5.0 V, Idd2 = 120 mA) dBm +25 Rx Pdiss Rx mode Total Power Dissipation [3] LNA1 W 0.3 Rx mode Total Power Dissipation [3] LNA2 W 0.5 Tx Pdiss Tx mode Total Power Dissipation W 11.2 Tj Junction Temperature °C 150 TSTG Storage Temperature °C -65 to 150 Tamb Ambient Temperature °C -40 to 85 Rx/Tx Switch Operating Truth Table [1] Mode Vbias (V) Vc1 (V) Vc2 (V) Rx (Ant – Rx) 5 28 0 Tx (Ant – Tx) 5 0 28 Note: 1. Any state other than described above in the truth table may cause permanent damage to the device. 2 LNA1: Vdd1 = 5.0 V, Idd1 = 50 mA LNA2: Vdd2 = 5.0 V, Idd2 = 120 mA; jc = 10.2°C/W Notes: 1. Operation of this device in excess of any of these limits may cause permanent damage. 2. Thermal resistance measured using Infra-Red Measurement Technique. 3. Power dissipation in Rx mode with both LNA1 and LNA2 turned on. Board temperature TB is 25° C. LNA1: Derate at 13.5 mW/°C for TB > 113° C. LNA2: Derate at 14.3 mW/°C for TB > 86° C. 4. Switch Turn On Condition: Tx mode: Vbias = 5 V, Vc1 = 0 V, Vc2 = 28 V Rx mode: Vbias = 5 V, Vc1 = 28 V, Vc2 = 0 V Electrical Specifications [1] Rx Mode TA = 25° C, Vbias = 5 V, Vc1 = 28 V, Vc2 = 0 V, Vdd1= 5 V, Vdd2 = 5 V, RF performance at 2.30 GHz, measured on demo board unless otherwise specified. Symbol Parameter and Test Condition Units Min. Typ. Max. Ibias Vbias current mA – 51.3 – Ic1 Vc1 current mA – 0.0 – Ic2 Vc2 current mA – -51.0 – Idd1 Vdd1 current mA – 55.1 – Idd2 Vdd2 current mA – 122.3 – Total Current Total max current consumption ( Ibias + Idd1 + Idd2 ) mA – 228.7 – NF Noise Figure dB – 0.97 – Gain Gain dB – 37.1 – OIP3 [2] Output Third Order Intercept Point dBm – 38.8 – OP1dB Output Power at 1 dB Gain Compression dBm – 23.4 – Isolation Isolation (LNA1_output to LNA2_input) dB – 54.5 – Rx Out RL LNA2 Output Return Loss dB – 18.7 – Ant RL Antenna Input Return Loss dB – 18.9 – Tx Mode TA = 25° C, Vbias = 5 V, Vc1 = 0 V, Vc2 = 28 V, RF performance at 2.30 GHz, measured on demo board unless otherwise specified. Symbol Parameter and Test Condition Units Min. Typ. Max. Ibias Vbias current mA – 41.0 – Ic1 Vc1 current mA – -51.0 – Ic2 Vc2 current mA – 10.0 – Tx Ant IL Tx Antenna Insertion Loss dB – 0.37 – Max Input Power [4] 50 W CW power (5 mins testing) at Antenna port dBm – – 47.5 Ant RL Antenna Input Return Loss dB – 24.0 – Notes: 1. Measurements at 2.30 GHz obtained using demo board described in Figure 12. 2. OIP3 test condition: FRF1 = 2.30 GHz and FRF2 = 2.301 GHz with input power of -25 dBm per tone measured at worst side band. 3. Use proper biasing, heat sink and de-rating to ensure maximum channel temperature is not exceeded. 4. Max Input Power was characterized during the product development stage. It is not final tested at production. 3 Electrical Specifications [1] Rx Mode TA = 25° C, Vbias = 5 V, Vc1 = 28 V, Vc2 = 0 V, Vdd1 = 5 V, Vdd2 = 5 V, RF performance at 2.40 GHz, measured on demo board unless otherwise specified. Symbol Parameter and Test Condition Units Min. Typ. Max. Ibias Vbias current mA 42.0 51.3 60.0 Ic2 Vc2 current mA -60.0 -51.0 -42.0 Idd1 Vdd1 current mA 30.0 55.1 60.0 Idd2 Vdd2 current mA 97.0 122.3 130.0 Total Current Total max current consumption ( Ibias + Idd1 + Idd2 ) mA – 228.7 250 NF Noise Figure dB – 0.99 1.25 Gain Gain dB 35 36.8 – OIP3 [2] Output Third Order Intercept Point dBm 36 38.5 – OP1dB Output Power at 1 dB Gain Compression dBm 22 22.7 – Isolation Isolation (LNA1_output to LNA2_input) dB – 54.2 – Rx Out RL LNA2 Output Return Loss dB – 20.0 – Ant RL Antenna Input Return Loss dB – 16.0 – Tx Mode TA = 25° C, Vbias = 5 V, Vc1 = 0 V, Vc2 = 28 V, RF performance at 2.40 GHz, measured on demo board unless otherwise specified. Symbol Parameter and Test Condition Units Min. Typ. Max. Ibias Vbias current mA 32.0 41.0 – Ic1 Vc1 current mA – -51.0 – Ic2 Vc2 current mA – 10.0 – Tx Ant IL Tx Antenna Insertion Loss dB – 0.40 0.60 Max Input Power [4] 50 W CW power (5 mins testing) at Antenna port dBm – – 47.5 Ant RL Antenna Input Return Loss dB – 20.8 – Notes: 1. Measurements at 2.40 GHz obtained using demo board described in Figure 12. 2. OIP3 test condition: FRF1 = 2.40 GHz and FRF2 = 2.401 GHz with input power of -25 dBm per tone measured at worst side band. 3. Use proper biasing, heat sink and de-rating to ensure maximum channel temperature is not exceeded. 4. Max Input Power was characterized during the product development stage. It is not fi nal tested at production. 4 ALM-12224 Rx mode Typical Over-Temperature Performance -10 -10 -12 -15 Output RL (dB) Ant RL (dB) -14 -16 -18 -20 25° C 85° C -40° C -22 -24 -20 -25 -30 25° C 85° C -40° C -35 -40 2.2 2.3 2.4 2.2 2.5 2.3 Figure 1. Ant Input Return Loss vs Frequency vs Temperature 40 Gain (dB) NF (dB) 1.00 0.50 25° C 85° C -40° C 2.2 2.3 2.4 2.5 Frequency (GHz) 42 40 38 36 25° C 85° C -40° C 34 2.4 Frequency (GHz) Figure 5. Output IP3 vs Frequency vs Temperature 35 2.2 2.3 2.4 Figure 4. Gain vs Frequency vs Temperature 44 2.3 37 Frequency (GHz) Figure 3. NF vs Frequency vs Temperature 2.2 38 36 0.00 OIP3 (dBm) 25° C 85° C -40° C 39 1.50 5 2.5 Figure 2. LNA2 Output Return Loss vs Frequency vs Temperature 2.00 32 2.4 Frequency (GHz) Frequency (GHz) 2.5 2.5 ALM-12224 Rx mode Typical Over-Temperature Performance 24 OP1dB (dBm) 23 22 21 25° C 85° C -40° C 20 2.2 2.3 2.4 2.5 Frequency (GHz) Figure 6. Output P1dB vs Frequency vs Temperature Figure 7. Idd1 Vs R1 ALM-12224 Tx mode Typical Over-Temperature Performance -18 -18 -20 Tx Output RL (dB) -20 Ant RL (dB) -22 -24 -26 25° C 85° C -40° C -28 2.3 2.4 -24 25° C 85° C -40° C -26 -30 2.2 -22 -28 2.5 2.2 2.3 Frequency (GHz) Figure 8. Ant Input Return Loss vs Frequency vs Temperature -30 25° C 85° C -40° C -35 -0.30 Isolation (dB) Insertion Loss (dB) -0.25 -0.35 -0.40 -40 -45 25° C 85° C -40° C -50 -0.45 -55 2.2 2.3 2.4 Frequency (GHz) Figure 10. Tx Antenna Insertion Loss vs Frequency vs Temperature 6 2.5 Figure 9. Tx Output Return Loss vs Frequency vs Temperature -0.20 -0.50 2.4 Frequency (GHz) 2.5 2.2 2.3 2.4 Frequency (GHz) Figure 11. Ant-LNA1_input Isolation vs Frequency vs Temperature 2.5 ALM-12224 S2p For Rx Mode (Vbias = 5 V, Vc1 = 28 V, Vc2 = 0 V, Tc = 25° C, matched 50 ) Freq GHz S11 S11 S12 S12 S13 S13 S21 S21 S22 S22 S23 S23 S31 S31 S32 S32 S33 S33 Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. 0.1 0.513 -165.0 0.001 -116.4 0.167 51.8 0.003 -127.7 0.823 173.1 0.001 56.6 0.169 53.1 0.001 -97.7 0.800 -43.5 0.3 0.810 -173.4 0.002 60.6 0.071 -5.4 0.048 -139.0 0.796 157.0 0.015 -105.3 0.074 -10.0 0.001 -155.8 0.847 -162.5 0.5 0.726 170.6 0.001 172.0 0.343 76.9 0.478 -106.6 0.754 139.0 0.604 -35.7 0.478 -106.6 0.754 139.0 0.604 -35.7 0.7 0.766 164.4 0.002 -50.5 0.327 47.5 2.933 -141.0 0.652 119.5 3.726 -114.1 0.314 43.7 0.003 41.6 0.611 -179.2 0.9 0.751 154.2 0.002 31.9 0.354 35.3 17.817 114.9 0.402 107.4 18.326 118.6 0.351 37.5 0.001 14.4 0.724 158.1 1.1 0.751 143.2 0.001 30.2 0.438 32.1 6.002 0.585 139.1 5.709 0.439 33.5 0.001 178.8 0.757 135.4 1.3 0.674 131.2 0.001 172.1 0.526 18.4 15.020 67.2 0.566 97.1 13.321 56.2 0.525 17.9 0.002 -43.6 0.684 117.2 1.5 0.575 138.2 0.002 -135.7 0.519 5.0 41.162 22.9 0.303 53.6 36.421 0.8 0.510 3.7 0.001 -115.9 0.647 100.3 1.7 0.440 121.0 0.002 137.2 0.567 -19.0 74.154 -55.7 0.129 -171.8 56.274 -84.0 0.542 -19.2 0.002 155.4 0.582 86.8 1.9 0.320 123.8 0.002 124.7 0.481 -42.8 79.263 -121.2 0.313 142.9 49.914 -160.9 0.462 -41.7 0.001 -118.1 0.631 66.5 2.1 0.228 135.6 0.001 73.1 0.312 -70.7 78.771 -173.7 0.267 123.9 32.451 135.1 0.314 -67.2 0.002 -168.1 0.740 33.2 2.3 0.206 173.0 0.002 64.9 0.078 -113.5 74.862 136.0 0.200 129.9 11.153 99.8 0.069 -120.4 0.002 -98.4 0.834 -9.5 2.31 0.207 171.6 0.001 -34.1 0.065 -119.4 74.649 133.8 0.207 128.9 10.359 101.2 0.064 -127.8 0.000 -131.9 0.842 -12.2 2.32 0.212 174.4 0.001 -0.4 0.054 -122.7 74.411 131.3 0.201 127.8 9.752 103.7 0.053 -127.7 0.002 130.5 0.840 -14.6 2.33 0.212 177.4 0.002 124.0 0.045 -128.6 73.878 128.9 0.191 129.2 9.223 106.4 0.051 -154.1 0.002 51.7 0.837 -16.8 2.34 0.225 178.5 0.001 55.5 0.034 -141.1 73.259 126.5 0.195 129.9 8.774 110.0 0.034 -148.9 0.001 -179.4 0.842 -19.4 2.35 0.238 -179.8 0.002 78.4 0.025 -161.2 72.465 124.0 0.200 134.5 8.531 114.3 0.032 164.1 0.001 45.0 0.846 -21.3 2.36 0.227 179.6 0.002 -38.1 0.020 170.2 72.345 121.3 0.189 130.0 8.381 118.2 0.038 148.0 0.002 53.3 0.844 -23.8 2.37 0.237 -178.3 0.001 -21.7 0.020 143.1 71.844 119.5 0.190 132.7 8.471 122.2 0.034 140.7 0.001 142.8 0.849 -26.1 2.38 0.239 -179.4 0.002 -11.9 0.028 114.7 70.973 117.0 0.195 131.2 8.625 126.5 0.048 115.8 0.002 51.0 0.848 -27.9 2.39 0.255 -178.8 0.002 52.8 0.035 103.8 70.812 114.5 0.201 133.8 8.953 129.6 0.048 110.2 0.002 158.2 0.854 -29.9 2.4 0.250 -176.6 0.003 -85.8 0.044 91.1 70.238 112.3 0.191 134.7 9.314 132.0 0.060 88.5 0.002 -70.9 0.852 -31.9 2.45 0.286 -175.7 0.002 50.3 0.089 73.2 67.550 100.8 0.195 139.3 11.897 136.2 0.106 78.3 0.002 131.2 0.840 -42.6 2.5 0.305 -175.2 0.003 32.5 0.133 63.8 64.460 89.5 0.193 139.9 14.780 132.3 0.157 64.4 0.001 82.3 0.831 -52.4 9.5 5.1 3 0.414 -177.5 0.001 -162.1 0.349 23.0 41.035 -0.4 0.263 142.9 24.498 33.7 0.353 20.2 0.001 1.5 0.735 -112.0 3.5 0.492 174.3 0.001 58.5 0.373 10.3 33.895 -76.6 0.250 123.4 24.948 -49.4 0.340 6.8 0.003 91.4 0.695 -138.3 4 0.446 151.6 0.002 170.4 0.464 12.8 30.915 -174.1 0.163 117.6 26.370 -153.3 0.486 17.1 0.002 175.8 0.598 -167.7 4.5 0.325 155.6 0.003 49.5 0.590 -7.0 13.479 89.8 0.139 56.8 12.798 106.9 0.596 -7.3 0.001 -33.8 0.406 -168.7 5 0.401 153.3 0.003 27.4 0.584 -21.7 6.090 26.1 0.059 -113.1 6.264 38.5 0.591 -21.5 0.002 16.4 0.355 -179.4 5.5 0.440 148.0 0.001 -135.2 0.579 -31.8 3.154 -29.2 0.242 165.6 3.489 -25.1 0.582 -31.5 0.002 43.0 0.326 158.1 6 0.472 137.7 0.003 -87.0 0.579 -41.9 1.765 -79.3 0.379 127.6 2.111 -79.1 0.591 -41.5 0.003 11.5 0.265 143.7 6.5 0.518 132.5 0.002 -124.9 0.593 -51.1 1.208 -127.0 0.485 105.3 1.592 -128.9 0.611 -51.6 0.003 -9.9 0.160 143.8 7 0.579 134.7 0.003 -118.0 0.596 -68.6 0.982 173.3 0.550 97.1 1.536 167.3 0.620 -70.1 0.002 174.8 0.272 -168.6 7.5 0.783 123.9 0.002 164.2 0.326 -84.7 0.455 95.7 0.576 95.2 0.972 77.4 0.312 -88.6 0.002 -155.7 0.675 154.4 8 0.696 130.5 0.003 175.5 0.448 -76.8 0.387 33.0 0.612 94.3 0.606 18.6 0.438 -77.7 0.001 -159.5 0.399 141.6 Note: 1. Port connection: Port 1 = Ant, Port 2 = Rx_Out and Port 3 = Tx 7 ALM-12224 S2p For Tx Mode (Vbias = 5 V, Vc1 = 0 V, Vc2 = 28 V, Tc = 25° C, matched 50 ) S11 S11 S12 S12 S13 S13 S21 S21 S22 S22 S23 S23 S31 S31 S32 S32 S33 S33 Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. Mag. Ang. 0.1 0.298 -167.0 0.002 -108.6 0.705 -7.3 0.002 -39.4 0.826 173.0 0.002 110.5 0.708 -7.2 0.002 -65.1 0.298 -168.4 0.3 0.777 -173.3 0.002 -54.4 0.281 -38.2 0.004 -63.8 0.796 157.2 0.006 -65.4 0.281 -37.9 0.001 -66.4 0.775 -170.0 0.5 0.724 147.8 0.001 18.8 0.447 37.5 0.073 24.6 0.751 139.3 0.065 18.9 0.073 24.6 0.751 139.3 0.065 18.9 0.7 0.612 129.8 0.002 -103.9 0.627 29.4 0.488 -23.8 0.645 120.0 0.410 -30.2 0.620 28.8 0.001 -61.3 0.619 137.9 0.9 0.339 116.3 0.001 99.3 0.835 17.1 4.741 -139.6 0.416 111.6 4.403 -136.7 0.836 16.8 0.002 46.8 0.400 109.9 1.1 0.128 116.0 0.000 -106.8 0.882 -3.1 3.636 100.3 0.595 137.3 3.415 94.7 0.873 -3.1 0.002 -176.6 0.192 135.4 1.3 0.386 -173.4 0.001 -118.0 0.582 -18.0 20.286 107.7 0.615 90.7 19.081 99.4 0.585 -17.6 0.002 53.0 0.440 169.3 1.5 0.331 169.5 0.003 -39.1 0.633 -9.2 48.731 -12.4 0.308 45.9 46.248 -21.5 0.622 -10.7 0.002 -32.9 0.389 155.4 1.7 0.514 136.7 0.003 27.0 0.656 14.7 45.477 -153.0 0.088 -124.1 43.532 -163.7 0.660 16.2 0.002 -0.7 0.537 119.0 1.9 0.298 109.6 0.001 -104.3 0.907 2.0 13.356 111.7 0.340 170.9 13.106 98.3 0.911 1.6 0.001 -16.8 0.284 88.5 2.1 0.131 107.9 0.002 -175.6 0.960 -9.1 3.164 59.3 0.377 138.4 3.246 42.4 0.960 -9.5 0.004 138.8 0.112 72.4 2.3 0.051 176.7 0.000 -121.9 0.976 -17.7 0.299 108.3 0.299 120.8 0.351 59.5 0.971 -17.3 0.001 138.4 0.007 -69.1 2.31 0.053 -176.7 0.002 -142.0 0.970 -17.9 0.318 121.5 0.298 121.2 0.328 71.5 0.973 -17.9 0.002 96.1 0.013 -85.9 2.32 0.056 -174.2 0.002 -90.6 0.969 -18.2 0.358 132.1 0.291 119.6 0.329 83.8 0.972 -18.4 0.001 86.4 0.020 -91.2 2.33 0.057 -168.2 0.001 -175.3 0.974 -18.6 0.405 139.3 0.288 120.1 0.350 93.9 0.971 -18.6 0.002 119.0 0.027 -100.5 2.34 0.060 -166.1 0.003 -160.9 0.971 -18.8 0.457 144.4 0.283 119.1 0.376 102.0 0.974 -18.8 0.001 -138.1 0.034 -104.5 2.35 0.065 -162.2 0.001 154.2 0.972 -19.2 0.509 147.4 0.277 118.8 0.414 107.8 0.973 -19.2 0.002 -122.6 0.040 -104.4 2.36 0.067 -159.5 0.002 -5.0 0.969 -19.8 0.565 149.3 0.276 119.7 0.457 111.7 0.974 -19.8 0.002 -164.1 0.047 -104.9 2.37 0.066 -155.5 0.001 88.9 0.971 -20.1 0.619 150.8 0.270 119.3 0.505 114.5 0.976 -19.8 0.001 15.0 0.052 -102.8 2.38 0.070 -153.9 0.001 166.8 0.968 -20.3 0.666 151.6 0.263 119.3 0.548 116.9 0.965 -20.5 0.002 148.4 0.056 -107.2 2.39 0.073 -149.8 0.002 26.8 0.973 -20.8 0.723 151.5 0.262 118.6 0.598 117.3 0.972 -20.8 0.002 22.0 0.059 -103.3 2.4 0.078 -149.4 0.001 -59.7 0.967 -21.1 0.768 151.4 0.255 119.0 0.640 117.9 0.970 -20.7 0.001 123.7 0.063 -106.5 2.45 0.104 -140.4 0.001 -169.9 0.962 -23.0 0.966 147.7 0.230 119.2 0.825 114.6 0.970 -22.7 0.001 14.9 0.081 -112.7 2.5 0.122 -138.1 0.001 34.7 0.965 -24.4 1.108 142.5 0.210 121.7 0.959 107.6 0.964 -24.4 0.002 173.5 0.110 -116.0 3 0.287 -136.1 0.001 165.5 0.924 -38.0 1.217 109.7 0.251 142.5 0.245 24.1 0.926 -38.3 0.002 -72.4 0.284 -131.0 3.5 0.352 -148.7 0.001 137.9 0.857 -47.4 3.328 72.8 0.189 115.6 2.377 94.8 0.856 -47.7 0.001 112.5 0.348 -148.5 4 0.371 -151.7 0.001 -145.9 0.877 -55.9 5.661 -40.6 0.231 123.7 5.282 -33.9 0.875 -56.4 0.002 47.5 0.370 -148.1 4.5 0.412 -166.1 0.003 65.2 0.857 -66.9 3.592 -129.6 0.156 52.5 3.707 -131.1 0.853 -67.5 0.004 143.4 0.406 -153.1 Freq GHz 5 0.457 -178.8 0.003 -145.1 0.800 -77.4 2.304 161.0 0.060 -114.0 2.535 152.6 0.800 -77.2 0.002 -172.4 0.429 -169.5 5.5 0.488 174.8 0.004 164.0 0.752 -87.7 1.515 98.2 0.246 164.5 1.712 81.1 0.749 -88.1 0.002 137.6 0.465 166.1 6 0.536 162.7 0.002 41.7 0.707 -99.6 0.973 43.4 0.378 125.8 1.163 22.3 0.703 -99.7 0.003 70.8 0.490 152.8 6.5 0.628 151.2 0.003 134.0 0.642 -111.3 0.686 -3.3 0.481 104.1 0.919 -28.1 0.635 -111.1 0.005 42.2 0.545 141.3 7 0.726 141.6 0.004 -151.5 0.548 -127.2 0.611 -49.2 0.544 97.0 0.977 -80.3 0.540 -125.4 0.006 6.8 0.697 126.6 7.5 0.844 125.2 0.004 -142.5 0.267 -150.3 0.684 -112.6 0.573 95.0 1.486 -167.1 0.290 -142.3 0.002 32.0 0.787 96.8 8 0.697 125.6 0.003 166.9 0.447 -97.8 0.413 137.7 0.602 93.5 0.669 93.9 0.454 -100.1 0.003 58.9 0.243 90.0 Note: 1. Port connection: Port 1 = Ant, Port 2 = Rx_Out and Port 3 = Tx 8 Demo Board Layout Top View C2 C10 C6 C7 C8 C1 L1 C9 R2 C5 C4 C3 R1 14 Pin Connector 1 7 Figure 12. Demo Board Layout Diagram – Recommended PCB material is 20 mils Rogers RO4350. – Suggested component values may vary according to layout and PCB material. – Optional LNA1_out and LNA2_In traces are electrically disconnected. Simplified Schematic Vc1 Vbias Table 1. Component list for 2.40 GHz Vdd2 C6 C10 Tx C7 C2 C8 Ant C1 L1 Vc2 C5 Vg C9 R1 Vdd1 Rx Out C3 C4 R2 LNA1 output LNA2 input Figure 13. Demo Board Schematic Diagram matching 9 Component Vendor Size Value C1 Murata 0805 18 pF C2 Murata 0805 12 pF C3 Murata 0805 4.7 F C4 Murata 0402 8.2 pF C5 Murata 0402 4.7 pF C6 Murata 0603 2.2 F C7 Murata 0402 0.1 F C8 Murata 0402 10 pF C9 Murata 0805 4.7 F C10 Murata 0805 4.7 F R1 KOA 0402 3.6 Kohm R2 KOA 0402 0 ohm L1 Murata 0402 27 nH 1.50 0.30 1.20 ±0.10 8.00 ±0.10 0.70 0.30 PIN 1 DOT BY MARKING 0.10 0.80 0.70 AVAGO 12224 WWYY XXXX 5.80 PIN #1 IDENTIFICATION CHAMFER 0.20 X 45° 1.50 PIN 1 0.80 5.80 8.00 ±0.10 0.80 0.30 0.80 1.50 1.50 TOP VIEW SIDE VIEW 1.00 0.10 BOTTOM VIEW Notes: 1. All dimensions are in millimeters. 2. Dimensions are inclusive of plating. 3. Dimensions ate exclusive of mold flash and metal burr. Figure 14. Package Drawing Dimensions 7.80 1.00 1.50 0.70 1.43 0.70 1.50 0.66 0.80 0.70 5.80 0.80 0.80 7.80 5.80 0.80 0.30 1.40 1.40 1.40 0.80 4.40 0.34 1.00 1.50 LAND PATTERN 1.15 1.43 1.40 STENCIL OPENING 2.50 5.00 7.74 7.80 0.70 0.66 7.80 5.80 5.20 0.34 0.30 0.20 Notes: 1. All dimensions are in millimeters. 2. Recommended stencil thickness (4 mil). 1.40 1.00 1.15 1.43 1.50 COMBINATION OF LAND PATTERN & STENCIL OPENING Figure 15. PC Board and stencil design 10 0.20 2.50 0.66 1.50 1.15 5.20 0.66 0.80 1.00 0.66 1.43 0.80 0.70 0.96 1.43 Device Orientation REEL USER FEED DIRECTION CARRIER TAPE USER FEED DIRECTION AVAGO 12224 WWYY XXXX TOP VIEW COVER TAPE Tape Dimensions Part Number Ordering Information Part # Qty Container ALM-12224-BLKG 100 Antistatic Bag ALM-12224-TR1G 1000 13” Reel 11 AVAGO 12224 WWYY XXXX AVAGO 12224 WWYY XXXX END VIEW Reel Dimensions - 13” Reel FRONT VIEW T Tape Start Slot CCD/KEAC MADE IN MALAYSIA 6 1.5 Mi n PS 20.2 Min 330 Max Diameter BACK VIEW CCD/KEAC MADE IN MALAYSIA SIDE VIEW 6 PS W1 Measured At Hub 13+/0.20 Arbor Hole Measured At Hub W2 TAPE WIDTH T 16 mm 7 ±0.50 W1 W2 W3 16.4 +2.0 22.4 Max 15.9 Min 0.0 19.4 Max W3 Measured At Outer Edge For product information and a complete list of distributors, please go to our web site: www.avagotech.com Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies in the United States and other countries. Data subject to change. Copyright © 2005-2011 Avago Technologies. All rights reserved. AV02-2956EN - October 14, 2011 100+/0.50 Hub Dia.