1.5 - 2.5 GHz Upconverter/ Downconverter Technical Data HPMX-5001 Features Plastic TQFP-32 Package * 2.7 V Single Supply Voltage * Low Power Consumption (60 mA in Transmit Mode, 39 mA in Receive Mode Typical) * 2 dBm Typical Transmit Power at 1900 MHz * Half-Frequency VCO with Frequency Doubler * 32/33 Dual-Modulus Prescaler * Flexible Chip Biasing, Including Standby Mode * TQFP-32 Surface Mount Package * Operation to 2.5 GHz The HPMX-5001 Upconverter/ Downconverter provides RF system designers with all of the necessary features to perform an RF-to-IF downconversion for a receive path, as well as an IF-toRF upconversion for transmit mode. -5001 HPMX YYWW ZZZ XXXX Pin Configuration 32 25 1 24 HPMX-5001 YYWW * Use with Companion HPMX-5002 IF chip XXXX Applications ZZZ 8 * DECT, UPCS and ISM Band Handsets and Basestations 17 9 16 Functional Block Diagram POWER DOWN CONTROL RX IF OUT RX RF IN EXT. VCO TANK X2 TX RF OUT 32/33 TX IF IN PRESCALER OUT General Description RATIO SELECT Designed to meet the unique needs of portable applications, the HPMX-5001 combines the qualities of flexible chip biasing, low power consumption, and true 2.7 V minimum supply voltage operation to provide superior performance and battery life. By incorporating the active elements of the VCO on-chip, as well as a 32/33 dual-modulus prescaler, overall system component count and costs are decreased. The 32-TQFP package insures that this high level of integration occupies a small amount of printed circuit board space. The HPMX-5001 can be used in either dual-conversion systems (with the HPMX-5002 IF Demodulator/Modulator) or single-conversion systems. The HPMX-5001 is manufactured using Agilent's HP-25 Silicon Bipolar Process with 25 GHz fT and 30 GHz fMax. 2 HPMX-5001 Absolute Maximum Ratings[1] Parameter VCC Supply Voltage Pin[4] Voltage at Any Power Dissipation[2,3] Min. -0.2 V Max. 8V -0.2 V VCC + 0.2 V 600 mW RF Input Power Junction Temperature Storage Temperature 15 dBm +150C -55C +125C Thermal Resistance[2]: jc = 100 C/W Notes: 1. Operation of this device in excess of any of these parameters may cause permanent damage. 2. TCASE = 25C. 3. Derate at 10 mW/C for TCASE > 90C. 4. Except CMOS logic inputs - see Summary Characterization Information table. 5. This product is ESD sensitive. Handle with care to avoid static discharge. HPMX-5001 Guaranteed Electrical Specifications Unless otherwise noted, all parameters are guaranteed under the following conditions: VCC = 3.0 V. Test results are based upon use of networks shown in test board schematic diagram (see Figure 28). Typical values are for VCC = 3.0 V, TA = 25C. Symbol GC Pout ICC VDIV Parameters and Test Conditions Receive Conversion Gain[1] Units dB Min. 12 Typ. 14 Input[2] 2:1 output VSWR Transmit Mode dBm mA 0 2 64 80 Receive Mode Synth Mode mA mA 43 15 54 19 Standby Mode (with DIVMC Set High) DIV Single-Ended Swing[3] A VPP 1 1 50 Transmitter Power Output Device Supply Current 0.7 Max. Notes: 1. 50 RF source, 100 MHz < IF < 300 MHz, 1.89 GHz RF. There is a 750 resistor on chip between RXIF and RXIFB (pins 3 and 4). A matching network from 750 to 50 is used for this measurement. Insertion loss of the matching network is included in the net conversion gain figure. See Figure 28. 2. Signal injected into P3 in Figure 28 is -12.5 dBm. 3. DIV output AC coupled into a 2 k || 10 pF load. See test board schematic diagram, Figure 28. 3 HPMX-5001 Summary Characterization Information Typical values measured on test board shown in Figure 28 at VCC = 3.0 V, TA = 25C, RXIF = 110.592 MHz, TXRF = 1.89 GHz, unless otherwise noted. Symbol Parameters and Test Conditions Units Typical V VCC - 0.8 VIL CMOS Input High Voltage (Can Be Pulled up as High as VCC + 7 V)[1] CMOS Input Low Voltage V VCC - 1.9 IIH IIL CMOS Input High Current CMOS Input Low Current A A < 10 > -300 ts th DIVMC Setup Time[2,8] DIVMC Hold Time[2,8] ns ns 4 0 tpd DIV Propagation Delay[2,8] Mode Switching Time[3] ns s <7 <1 VIH Receive Mode Gc NF IIP3 IP1dB VSWRin dB 1.89 GHz 14 Noise Figure[4] Input Third Order Intercept Point dB dBm 10 -8 10 -9 Input 1 dB Gain Compression Point LO Leakage (2 x fVCO) at IF Port Input VSWR[5] dBm dBm -18 -57 1.3:1 -18 -- 1.3:1 dBm -- -5 Output 1 dB Gain Compression Point Output VSWR dBm 0 1.8:1 0 1.8:1 LO Suppression (2 x fVCO) IF 3 dB Bandwidth dBc MHz 25 500 30 500 dBc/Hz +137 +134 MHz 750-1200 Receive Conversion Gain [9] Transmit Mode[6] PIM 3 Power Output Level for >35 dB IM3 Suppression[10] OP1dB VSWRout F3dBIF Transmitter C/N @ 2 x fVCO + 4 MHz[11] 2.45 GHz 13.5 Synth Mode 1LO Frequency Range[7] Notes: 1. All CMOS logic inputs are internally pulled up to logic high level. 2. See Figure 2 for detailed timing diagram. 3. Between any two different biasing modes. This switching time does not include PLL lock-up time. 4. Single sideband noise figure. 5. In modes other than receive, the VSWR may be as high as 10:1. 6. Single-ended 50 RF load, 300 series IF terminations (600 differential), 100 MHz < IF < 300 MHz, 1.89 GHz RF. 7. The LO is followed by a frequency doubler which raises the LO range to 1500-2400 MHz. 8. DIV output AC coupled into a 2 k || 10 pF load. See test diagram, Figure 28. 9. 50 RF source, 110 MHz < IF < 300 MHz, 1.89 GHz or 2.45 GHz RF. There is a 750 resistor on chip between RXIF and RXIFB (pins 3 and 4). A matching network from 750 to 50 is used for this measurement. Insertion loss of the matching network is included in the net conversion gain figure. 10. PIM3 is the maximum SSB output power for at least 35 dB IM3 spur suppression. 11. Measured at saturated output power for 1.89 GHz. Measured at -5 dBm SSB output power for 2.45 GHz. 4 Table 1 - HPMX-5001 Pin Description No. 1 Mnemonic TXCTRL I/O Type CMOS I/P Description Controls biasing of transmit mixer, amplifiers, and doubler 3 RXIFB Analog O/P 4 RXIF Analog O/P 5 6 TXIF TXIFB Analog I/P Analog I/P 7 8 LNAREF RXRF Analog DC I/P Analog I/P 10 11, 15 TXRXVCC TXRXGND DC Supply Ground Supply voltage for transmit path, receive front-end and mixer Ground for transmit path, receive front-end and mixer 12 TXRFB Analog O/P 14 TXRF Analog O/P Inverting output of transmit path (see test diagram for matching network) Non-inverting output of transmit path (see test diagram for matching network) 16 17 DBLVCC DBLGND DC Supply Ground Supply voltage for LO frequency doubler Ground for LO frequency doubler 20 21 22 VCOTNKS VCOTNKF VCOVCC Analog I/P Analog O/P DC Supply Sense line from external tank circuit to on-chip VCO amplifier Force line from on-chip VCO amplifier to external tank circuit Supply voltage for on-chip VCO amplifier 23 26 VCOGND DIVVCC Ground DC Supply Ground for on-chip VCO amplifier Supply voltage for 32/33 dual-modulus prescaler 27 28 DIVGND DIV Ground Analog O/P Ground for 32/33 dual-modulus prescaler Output from 32/33 dual-modulus prescaler 30 31 DIVMC LOCTRL CMOS I/P CMOS I/P Modulus control signal for 32/33 dual-modulus prescaler Controls biasing for VCO and 32/33 dual modulus prescaler 32 2, 9, 13, 18, 19, 24, 25, 29 RXCTRL VSUB CMOS I/P Ground Controls biasing for receive mixer, amplifiers, and doubler Substrate bias voltage Inverted single-ended downconverted receiver output, normally tied to VCC (internal 750 resistor connects to RXIF) Single-ended downconverted receiver output, drives SAW filter (internal 750 resistor connects to RXIFB) Transmit non-inverting IF input Transmit inverting IF input Reference input for receive input amplifier Receive RF input Table 2 - HPMX-5001 Mode Control (CMOS Logic Levels - all pins internally pulled up to high level) Mode Transmit TXCTRL 0 RXCTRL 1 LOCTRL 0 Receive Synth 1 1 0 1 0 0 Standby 1 1 1 5 31 32 1 2 16 17 18 19 32 33 1 2 19 32 1 2 3 VCO DIV DIVMC DIVIDE BY 33 (DIVMC = 0) 31 33 1 2 16 17 18 VCO tpd DIV DIVMC ts th DIVIDE BY 32 (DIVMC = 1) Figure 2. HPMX-5001 Prescaler Timing Diagram. TX PA CERAMIC TX FILTER TX IF INPUT LO1 X2 T/R TANK FRONT-END RF FILTER RX LNA 32/33 CERAMIC IMAGE FILTER HPMX-5001 RX IF FILTER RX IF OUTPUT Figure 3. HPMX-5001 Block Diagram/Typical Application. 30 MHz SYNTHESIZER REFERENCE OSCILLATOR 6 TX PA CERAMIC TX. FILTER 10.368 MHz REFERENCE OSCILLATOR LO1 900 MHz X2 T/R TANK FRONT-END RF FILTER RX LNA 30 MHz SYNTHESIZER 32/33 CERAMIC IMAGE FILTER HPMX-5001 IF1 = 110.592 MHz SAW CHANNEL FILTER IF2 = 6.912 MHz LC FILTER LC FILTER DATA FILTER CHARGE PUMP DATA SLICER RX DATA RSSI o FREQ. DET. 90/216 CHARGE PUMP TANK 9/12/16 LOCK DET. RC FILTER LO2 = 103.68 MHz TX DATA LC FILTER Figure 4. Typical HPMX-5001 Application with HPMX-5002 IF Chip. All Other Connections Go to Burst Mode Controller, Power Source, or Ground. VCC = 5.5 V 8 6 VCC = 3.0 V 4 2 VCC = 2.7 V -15 5 25 45 65 TEMPERATURE (C) Figure 5. ICC in Standby Mode vs. Temperature and VCC. 85 46 ICC SYNTHESIZER MODE (mA) 10 0 -55 -35 17 48 ICC RECEIVE MODE (mA) ICC STANDBY MODE (A) 12 VCC = 5.5 V 44 VCC = 3.0 V 42 VCC = 2.7 V 40 38 36 -55 -35 -15 5 25 45 65 TEMPERATURE (C) Figure 6. ICC in Receive Mode vs. Temperature and VCC. 85 16 VCC = 5.5 V VCC = 3.0 V 15 VCC = 2.7 V 14 13 -55 -35 -15 5 25 45 65 85 TEMPERATURE (C) Figure 7. ICC in Synthesizer Mode vs. Temperature and VCC. 7 65 VCC = 3.0 V VCC = 2.7 V 60 2.0 2.0 1.8 1.8 1.6 1.4 VCC = 2.7 V 1.2 1.4 VCC = 2.7 V 1.2 5 25 45 65 85 25 45 65 85 0 RECEIVE MIXER (dBm) VCC = 5.5 V VCC = 2.7 V 8 6 4 2 -15 5 25 45 65 -5 -10 P1dB -20 0 -10 -20 -30 -40 VCC = 5.5 V -50 VCC = 2.7 V -60 25 45 5 25 45 65 85 65 85 TEMPERATURE (C) Figure 14. 2 x fLO Leakage at Receive Downconverter Output vs. Temperature and VCC. 65 85 14.5 VCC = 2.7 V 14.0 13.5 VCC = 5.5 V 13.0 12.5 12.0 -55 -35 -15 5 25 45 65 85 TEMPERATURE (C) Figure 12. Receive Downconverter Input Third Order Intercept Point and Output 1 dB Compression Point vs. Temperature and VCC. TRANSMIT 2 x fLO SUPPRESSION (dBc) Figure 11. Receive Downconverter SSB Noise Figure vs. Temperature and VCC. 5 -15 45 15.0 TEMPERATURE (C) TEMPERATURE (C) -15 VCC = 5.5 V -15 -25 -55 -35 85 VCC = 2.7 V INPUT IP3 25 Figure 10. Receive Downconverter Output VSWR vs. Temperature and VCC. Figure 13. Receive Downconverter Conversion Gain vs. Temperature and VCC. 3.0 40 35 30 VCC = 2.7 V 25 TXRF VSWR (OUTPUT) 10 5 -15 TEMPERATURE (C) Figure 9. Receive Downconverter Input VSWR vs. Temperature and VCC. 12 -70 -55 -35 5 TEMPERATURE (C) Figure 8. ICC in Transmit Mode vs. Temperature and VCC. 0 -55 -35 -15 VCC = 5.5 V 1.0 -55 -35 RECEIVE MIXER CONVERSION GAIN (dB) -15 1.0 -55 -35 TEMPERATURE (C) RECEIVE MIXER SSB NOISE FIGURE (dB) 1.6 VCC = 5.5 V 55 -55 -35 2 x fLO LEAKAGE (dBm) RXRF VSWR (OUTPUT) VCC = 5.5 V RXRF VSWR (INPUT) ICC TRANSMIT MODE (mA) 70 VCC = 5.5 V 20 15 10 2.6 2.2 VCC = 2.7 V 1.8 VCC = 5.5 V 1.4 5 0 -55 -35 -15 5 25 45 65 TEMPERATURE (C) Figure 15. 2 x fLO Suppression at Transmit Upconverter Output vs. Temperature and VCC. 85 1.0 -55 -35 -15 5 25 45 65 TEMPERATURE (C) Figure 16. Transmit Upconverter Output VSWR vs. Temperature and VCC. 85 1.05 3.0 VCC = 5.5 V 137.5 137.0 VCC = 2.7 V 136.5 136.0 135.5 135.0 -55 -35 -15 5 25 45 65 VCC = 5.5 V 2.0 1.0 0 P1dB VCC = 2.7 V -1.0 TEMPERATURE (C) -15 5 25 45 65 TEMPERATURE (C) Figure 17. Carrier to Noise Ratio at Transmit Upconverter Output vs. Temperature and VCC. Figure 18. Transmit Upconverter Power Output and Output 1 dB Compression Point vs. Temperature and VCC. DIVVCC PIN 26 RECOMMENDED OUTPUT CIRCUIT C = 2.2 nF, R = 51 PIN 28 DIV o/p C 1.00 VCC = 5.5 V VCC = 2.7 V 0.95 0.90 -2.0 -3.0 -55 -35 85 VCC = 3.0 V POUT DIV OUTPUT (Vp-p) 138.0 TRANSMIT MIXER (dBm) TRANSMIT CARRIER TO NOISE RATIO (dB) 8 R MAX. LOAD C = 10 pf, R = 2k PIN 27 DIVGND Figure 20. Equivalent Circuit and Recommended Output and Load Circuits for the HPMX-5001 Prescaler Output. 85 0.85 -55 -35 -15 5 25 45 65 85 TEMPERATURE (C) Figure 19. Prescaler Output Voltage vs. Temperature and VCC. 9 DIVVCC PIN 26 PIN 30 DIVMC i/p LOW = 1/33 OPEN OR VCC = 1/32 PIN 27 DIVGND Figure 21. Equivalent Circuit for the Divider Modulus Control. VCOVCC , PIN 22 TO USE WITH INJECTED LO SIGNAL, DRIVE PIN 20 (VCOTNKS) WITH 630 m Vp-p. LEAVE PIN 21 (VCOTNKF) FLOATING AS SHOWN BELOW. C = 22 p MAX. FOR MINIMAL TURN ON DELAYS. 7k PIN 20 20 PIN 21 OPTIONAL FOR SWR 21 VCOGND, PIN 23 Figure 22. Equivalent Circuit for VCO Tank Connection and Recommended Tank Circuit. VCC ALL LOGIC CONTROL PINS ARE ACTIVE LOW. OPEN OR VCC = NOT ACTIVE. TXCTRL, PIN 1 LOCTRL, PIN 31 RXCTRL, PIN 32 GND Figure 23. Equivalent Circuit for Logic Control Pin 1, 31, and 32. 10 TXRX VCC 10 BIAS TO MIXER RXRF 50 i/p 2.7 pF BIAS 8 LNAREF 7 11 3.3 pF LNA STAGE PCB GND 15 EXTERNAL COMPONENTS ARE FOR TYPICAL i/p SWR OF 1.3:1 OVER 1.85 TO 2.55 GHz TXRX GND Figure 24. Equivalent Circuit for RXRF Input. TXRX VCC 10 RECOMMENDED DRIVE LEVEL IS 300 mV pk-pk. 10 k TXIF IN 10 k TXIF 5 TXIFB 6 USE d.c. BLOCKING Cs TO AVOID CHANGING d.c. BIAS CONDITIONS. 22 pF MAX. FOR QUICK TURN ON. TX i/p STAGE 11/15 TXRX GND Figure 25. Equivalent Circuit for TXIF Input. VCC 3 RXIFB 750 120 nH 4 RXIF 6.8 pF 8.2 pF 50 o/p LO EXTERNAL COMPONENTS SHOWN ARE FOR 110.592 MHz I.F. AND TYPICAL 50 o/p SWR OF 1.3:1 RF 11/15 TXRX GND Figure 26. Equivalent Circuit for the RXIF Output and Recommended Matching Circuit for 110.592 MHz IF. 11 VCC 3.3 nH 12 50 TXRFB 300 3.3 nH 14 50 o/p TXRF 22 pF EXAMPLE o/p NETWORK FOR 1.88-1.90 GHz. OTHER SYMMETRIC NETWORKS WILL ENABLE OPERATION UP TO 2.50 GHz. 11/15 TXRX GND TX o/p STAGE Figure 27. Equivalent Circuit for TXRF Output and Matching Network for DECT Phone Operation. P9 P8 R8 R7 C11 R9 P7 R5 C10 C9 P10 C12 32 25 24 1 R10 P1 C13 C1 + 32/33 L1 C2 RXIF R4 C3 X2 TXIF R6 VCOTNKS T1 C4 C8 R1 C5 RXRF C6 8 17 16 9 VCC Ground X3 R2 L2 C7 TXRF L3 Figure 28. Test Board Schematic Diagram. All I/O Labels Correspond to Those on the Test board. See Table 3 for Component Values. 12 Table 3. Test Board Components Shown in Figure 28. Functional Description Note: Required VCC decoupling capacitors are not shown on the schematic. Detailed schematic and board layout are available in Application Note 1081. A typical DECT application of the HPMX-5001 in a dual-conversion superheterodyne radio transceiver is shown in Figure 3. The HPMX-5001 is designed to provide four different modes of operation: Component Label Value (Size) R1 R2, R4, R5 270 (0805) 51.1 (0805) X3 R6 R = 300 (0805) for 1.89 GHz, L = 3.3 nH for 2.45 GHz 20 (0805) R7, R8, R9, R10 C1 1100 (0805) see Table 4 C2 C3, C4, C10, C11, C12, C13 see Table 4 1 nF (0805 or 0504) C5 C6 3.3 pF (0504 or 0603) 2.7 pF (0805) C7 C8 22 pF (0805) for 1.89 GHz, 3.3 pF for 2.45 GHz 12 pF (0805 or 0504) C9 L1 2.2 nF (0805) see Table 4 L2, L3 T1 3.3 nH (0805) 1:4 Balun T4-1-X65 Table 4. Component changes for dfferent IF frequencies. IF Frequency 110 MHz 200 MHz 250 MHz 300 MHz 350 MHz C1, pF 6.8 1.0 1.2 1.2 2.7 C2, pF 8.2 3.9 3.9 3.9 2.7 L1, nH 120 100 56 39 27 VSWR 1.3:1 1.3:1 1.3:1 1.3:1 1.3:1 * Transmit, where the VCO, doubler, upconverting mixer, associated buffers, and prescaler are enabled * Receive, where the VCO, doubler, downconverting mixer, associated buffers, and prescaler are enabled * Synthesizer, where only the VCO and prescaler are active * Standby, where all circuits are disabled These four modes are controlled via a three wire interface, TXCTRL, RXCTRL, and LOCTRL. Figure 1 shows the programming logic states for all four modes. The detailed description of the three active modes is given below. 13 Transmit Mode For transmit upconversion, a differential narrow-band modulated signal is AC-coupled into the TXIF and TXIFB inputs. The differential signal may be generated by the HPMX-5002 IF Demodulator/Modulator. Once on-chip, the signal is buffered and applied to a double-balanced Gilbert cell mixer. The upconverted RF signal is then amplified to generate a -0.6 dBm single-ended, single-sideband power signal at the 1 dB compression point. The RF outputs, TXRF and TXRFB, are open-collector outputs (see test diagram Figure 28 for recommended matching network). The TXRF output is AC-coupled into a 50 transmit filter. This signal is then filtered and amplified offchip by an external power amplifier before it is switched into the antenna. The HPMX-5001 may also be used in DECT systems which utilize direct modulation of the 1LO for data transmission. In this case, either the TXIF or TXIFB input, but not both, must be tied to VCC to cause the upconverting mixer to act as a buffer stage. Receive Mode In receive mode, a preamplified RF signal is passed through an image filter and applied as a single-ended signal to the 50 RXRF input. Use of a 2.7 pF blocking capacitor is recommended. RXRF is the noninverting input of the RF input amplifier. The inverting input of this amplifier, LNAREF, is selfbiased and requires only an external capacitor (recommended value of 3.3 pF) to ground. The receive downconversion mixer also employs a double-balanced Gilbert cell configuration. The production version of the HPMX-5001 will have two equivalent open collector outputs. The HPMX-5001 can operate at IF frequencies up to 300 MHz (see Figure 28 for recommended matching network). Synthesizer Mode The on-chip 32/33 dual-modulus prescaler, in conjunction with the VCO, external tank circuit, and CMOS synthesizer, form a phaselocked loop (PLL). The prescaler divider output and modulus control input are designed to be compatible with positive-edge triggered CMOS synthesizers from a variety of vendors. The timing requirements for the prescaler are shown in Figure 2. It is important to note that the prescaler divides the VCO signal, and not the frequency doubler output. Local oscillator (LO) signal generation on the HPMX-5001 is accomplished through the combination of a VCO and frequency doubler. The VCO is a simple Clapp oscillator for the best possible noise performance. The VCO force and sense pins (VCOTNKF, VCOTNKS) are self-biased, so that the connections to the tank (minimum Q of 20) are through AC-coupling capacitors. VCOTNKS can also be used with an injected LO. VCOTNKF would then be left floating. The doubler circuit multiplies the VCO frequency by two. This enables the VCO to have lower sensitivity to both package parasitics and LO re-radiation. Separate bias pins and buffering are utilized to minimize pulling of the VCO when the chip is switched from synthesizer to transmit or receive mode. 14 Part Number Ordering Information Part Number HPMX-5001-STR No. of Devices 10 Container Strip HPMX-5001-TR1 HPMX-5001-TY1 1000 250 Tape and Reel Tray Package Dimensions 32 Pin Thin Quad Flat Package All dimensions shown in mm. 9.0 0.25 7.0 0.1 9.0 0.25 HPMX-5001 YYWW XXXX 0.35 TYP. 7.0 0.1 ZZZ 0.8 1.4 0.05 0.6 + 0.15 - 0.10 0.05 MIN., 0.1 MAX. 15 Tape Dimensions and Product Orientation for Outline TQFP-32 REEL CARRIER TAPE USER FEED DIRECTION COVER TAPE 2.0 (See Note 7) 0.30 0.05 1.5+0.1/-0.0 DIA 4.0 (See Note 2) 1.75 R 0.5 (2) HPMX-5001 1.6 (2) BO 5.0 K1 KO 7.5 (See Note 7) 6.4 (2) AO 12.0 1.5 Min. Cover tape width = 13.3 0.1 mm Cover tape thickness = 0.051 mm (0.002 inch) AO = 9.3 mm BO = 9.3 mm KO = 2.2 mm K1 = 1.6 mm NOTES: 1. Dimensions are in millimeters 2. 10 sprocket hole pitch cumulative tolerance 0.2 3. Chamber not to exceed 1 mm in 100 mm 4. Material: black conductive AdvantekTM polystyrene 5. AO and BO measured on a plane 0.3 mm above the bottom of the pocket. 6. KO measured from a plane on the inside bottom of the pocket to the top surface of the carrier. 7. Pocket position relative to sprocket hole measured as true position of pocket, not pocket hole. 16.0 0.3 www.semiconductor.agilent.com Data subject to change. Copyright (c) 1999 Agilent Technologies Obsoletes 5965-9105E 5968-2384E (11/99)