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 Product Specification
PE9763
Product Description
Peregrine's PE9763 is a high performance fractional-N PLL capable of frequency synthesis up to 3.2 GHz. The device is designed for superior phase noise performance while providing an order of magnitude reduction in current consumption, when compared with the existing commercial space PLLs. The PE9763 features a 10/11 dual modulus prescaler, counters, a delta sigma modulator, a phase comparator and a charge pump as shown in Figure 1. Counter values are programmable through either a serial interface or directly hardwired. PE9763 is optimized for commercial space applications. Single Event Latch up (SEL) is physically impossible and Single Event Upset (SEU) is better than 10-9 errors per bit / day. Fabricated in Peregrine's patented UTSi(R) (Ultra Thin Silicon) CMOS technology, the PE9763 offers excellent RF performance and intrinsic radiation tolerance. 3.2 GHz Delta-Sigma modulated Fractional-N Frequency Synthesizer for Low Phase Noise Applications Features * 3.2 GHz operation * /10/11 dual modulus prescaler * Selectable phase detector or charge pump output * Serial or Direct mode access * Frequency selectivity: Comparison frequency / 218 * Low power --- 25 - 30 mA at 3V (phase detector / charge pump) * Rad-Hard * Ultra-low phase noise * 68-lead CQFJ or Die
Figure 1. Block Diagram
Fin Fin M8:0 A3:0 R5:0 Pre_en Sdata Primary 21-bit Latch
Prescaler 10/11
Main Counter 13 PD_U
20 Secondary 20-bit Latch Auxiliary 20-bit Latch
+
13 20 18 DSM 19 4 6 6 Phase Detector
PD_D Charge Pump CP
fr 18 K17:0 Direct 2
R Counter
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PE9763
Product Specification
Figure 2. Pin Configuration
RAND_EN MS2_SEL CPSEL GND GND
61
ENH
VDD
VDD
63
FR
62
R5
R4
R3
R2
R1
R0
K1
K0
68
67
65
66
64
9
7
6
4
2
8
5
3
1
VDD 10 K2 K3
11 12
60 59 58 57 56 55 54 53 52 51 50 49 48 47 46 45 44 27 V DD 28 GND 29 M 0 30 M 1 31 M 2 32 M3 33 M4 34 M5 35 M6 36 M7 37 M8 38 A0 39 A1 40 A2 41 A3 42 DIRECT 43 PRE_EN
VDD VDD GND PD_U CP PD_D GND VDD DOUT LD CEXT GND FIN FIN VDD GND VDD
K4 13 K5 14 K6 15 K7 16 K8 17 K9 18 K10 K11 K12 K13
19 20 21 22
K14 23 K15
24
K16 25 K17 26
Table 1. Pin Descriptions
Pin No.
1 2 3 4 5 6 7 8 9 GND VDD 10 VDD 11 12 13 14 15 K2 K3 K4 K5 K6 Direct Direct Direct Direct Direct (Note 1) Input Input Input Input Input Digital core VDD. K Counter bit2. K Counter bit3. K Counter bit4. K Counter bit5. K Counter bit6. Document No. 70-0140-01 UltraCMOSTM RFIC Solutions Downbond (Note 1) ESD ground. ESD VDD.
Pin Name
R0 R1 R2 R3 R4 R5 K0 K1 GND
Valid Mode
Direct Direct Direct Direct Direct Direct Direct Direct
Type
Input Input Input Input Input Input Input Input Downbond R Counter bit0 (LSB). R Counter bit1. R Counter bit2. R Counter bit3. R Counter bit4. R Counter bit5 (MSB). K Counter bit0 (LSB). K Counter bit1. Digital core ground.
Description
(c)2005 Peregrine Semiconductor Corp. All rights reserved. Page 2 of 15
PE9763
Product Specification
Pin No.
16 17 18 19 20 21 22 23 24 25 26 27
Pin Name
K7 K8 K9 K10 K11 K12 K13 K14 K15 K16 K17 VDD VDD GND
Valid Mode
Direct Direct Direct Direct Direct Direct Direct Direct Direct Direct Direct
Type
Input Input Input Input Input Input Input Input Input Input Input (Note 1) (Note 1) Downbond Downbond K Counter bit7. K Counter bit8. K Counter bit9. K Counter bit10. K Counter bit11. K Counter bit12. K Counter bit13. K Counter bit14. K Counter bit15. K Counter bit16. K Counter bit17 (MSB). Digital core VDD. ESD VDD. Digital core ground. ESD ground. M Counter bit0 (LSB). M Counter bit1. M Counter bit2 M Counter bit3. M Counter bit4.
Description
28 GND 29 30 31 32 M0 M1 M2 M3 M4 33 S_WR M5 34 SDATA M6 35 SCLK 36 37 38 M7 M8 A0 A1 39 E_WR 40 41 42 43 44 45 GND Downbond ESD ground. A2 A3 DIRECT Pre_en VDD GND Direct Direct Direct Direct Direct Serial Direct Serial Direct Serial Direct Direct Direct Direct Serial Direct Direct Both Direct Input Input Input Input Input Input Input Input Input Input Input Input Input Input Input Input Input Input Input (Note 1) Downbond
Serial load enable input. While S_WR is "low", Sdata can be serially clocked. Primary register data are transferred to the secondary register on S_WR or Hop_WR rising edge. M Counter bit5. Binary serial data input. Input data entered MSB first. M Counter bit6. Serial clock input. SDATA is clocked serially into the 20-bit primary register (E_WR "low") or the 8-bit enhancement register (E_WR "high") on the rising edge of Sclk. M Counter bit7. M Counter bit8 (MSB). A Counter bit0 (LSB). A Counter bit1. Enhancement register write enable. While E_WR is "high", Sdata can be serially clocked into the enhancement register on the rising edge of Sclk. A Counter bit2. A Counter bit3 (MSB). Direct mode select. "High" enables direct mode. "Low" enables serial mode. Prescaler enable, active "low". When "high", Fin bypasses the prescaler. Digital core VDD. Digital core ground.
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PE9763
Product Specification
Pin No.
Pin Name
VDD
Valid Mode
Type
(Note 1) (Note 1) ESD VDD. Prescaler VDD.
Description
46 VDD 47 48 Fin Fin Both GND 49 GND GND 50 CEXT Downbond Downbond Downbond Output Both Input Input Prescaler input from the VCO. 3.2 GHz max frequency. Prescaler complementary input. A bypass capacitor should be placed as close as possible to this pin and be connected in series with a 50 W resistor directly to the ground plane. Prescaler ground. Prescaler ground. Output driver/charge pump ground. Logical "NAND" of PD_U and PD_D terminated through an on chip, 2 kW series resistor. Connecting Cext to an external capacitor will low pass filter the input to the inverting amplifier used for driving LD. Lock detect and open drain logical inversion of CEXT. When the loop is in lock, LD is high impedance, otherwise LD is a logic low ("0"). Data out function, enabled in enhancement mode. Output driver/charge pump VDD. Output driver/charge pump ground. PD_D pulses down when fp leads fc . PD_U is driven to GND when CPSEL = "High". Charge pump output. Selected when CPSEL = "1". Tristate when CPSEL = "Low". PD_U pulses down when fc leads fp. PD_D is driven to GND when CPSEL = "High". Output driver/charge pump ground. Output driver/charge pump VDD. Phase detector GND. Phase detector VDD. ESD VDD. ESD ground. Reference ground. Reference frequency input. Reference VDD. Digital core VDD. Digital core ground. Enhancement mode. When asserted low ("0"), enhancement register bits are functional. Charge pump select. "High" enables the charge pump and disables pins PD_U and PD_D by forcing them "low". A "low" Tri-states the CP and enables PD_U and PD_D. MASH 1-1 select. "High" selects MASH 1-1 mode. "Low" selects the MASH 1-1-1 mode. K register LSB toggle enable. "1" enables the toggling of LSB. This is equivalent to having an additional bit for the LSB of K register. The frequency offset as a result of enabling this bit is the phase detector comparison frequency / 219.
Both Both Both
51 52 53 54 55 56 57 58 59
LD DOUT VDD GND PD_D CP PD_U GND VDD GND VDD
Output Output (Note 1) Downbond
Both Both Both
Output Output Output Downbond (Note 1) Downbond (Note 1) (Note 1) Downbond Downbond
60 VDD GND 61 GND 62 63 64 fr VDD VDD GND 65 66 67 68 Note 1: Note 2: ENH CPSEL MS2_SEL RND_SEL Both Both Both Both Input (Note 1) (Note 1) Downbond Input Input Input Input
Both
All VDD pins are connected by diodes and must be supplied with the same positive voltage level. All digital input pins have 70 k pull-down resistors to ground.
(c)2005 Peregrine Semiconductor Corp. All rights reserved. Page 4 of 15
Document No. 70-0140-01 UltraCMOSTM RFIC Solutions
PE9763
Product Specification
Table 2. Absolute Maximum Ratings
Symbol
VDD VI II IO Tstg
Electrostatic Discharge (ESD) Precautions
Units
V V mA mA C 4.0
Parameter/Conditions
Supply voltage Voltage on any input DC into any input DC into any output Storage temperature range
Min
-0.3 -0.3 -10 -10 -65
Max
VDD + 0.3 +10 +10 150
When handling this UltraCMOSTM device, observe the same precautions that you would use with other ESD-sensitive devices. Although this device contains circuitry to protect it from damage due to ESD, precautions should be taken to avoid exceeding the rating specified in Table 4. Latch-Up Avoidance
Table 3. Operating Ratings
Symbol
VDD TA
Unlike conventional CMOS devices, UltraCMOSTM devices are immune to latch-up.
Min
2.85 -40
Parameter/Conditions
Supply voltage Operating ambient temperature range
Max
3.15 85
Units
V C
Table 4. ESD Ratings
Symbol
VESD Note 1:
Parameter/Conditions
ESD voltage human body model (Note 1)
Level
1000
Units
V
Periodically sampled, not 100% tested. Tested per MILSTD-883, M3015 C2
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PE9763
Product Specification
Table 5. DC Characteristics
VDD = 3.0 V, -40 C < TA < 85 C, unless otherwise specified
Symbol
IDD
Parameter
Operational supply current; Prescaler enabled, charge pump disabled
Conditions
VDD = 2.85 to 3.15 V
Min
Typ
25
Max
Units
mA
IDD IDD IDD
Operational supply current; Prescaler enabled, charge pump enabled Operational supply current; Prescaler disabled, charge pump disabled Operational supply current; Prescaler disabled, charge pump enabled
VDD = 2.85 to 3.15 V VDD = 2.85 to 3.15 V VDD = 2.85 to 3.15 V
30 mA 10 mA 15 mA
All Digital inputs: K[17:0], R[5:0], M[8:0], A[3:0], Direct, Pre_en, Rand_en, M2_sel, Cpsel, Enh (contains a 70 k pull-down resistor) VIH VIL IIH IIL High level input voltage Low level input voltage High level input current Low level input current VDD = 2.85 to 3.15 V VDD = 2.85 to 3.15 V VIH = VDD = 3.15 V VIL = 0, VDD = 3.15 V -1 0.7 x VDD 0.3 x VDD +100 V V A A A A
Reference Divider input: fr IIHR IILR High level input current Low level input current VIH = VDD = 3.15 V VIL = 0, VDD = 3.15 V -100 +100
Counter and phase detector outputs: PD_D, PD_U VOLD VOHD Output voltage LOW Output voltage HIGH Iout = 6 mA Iout = -3 mA Iout = 200 A Iout = -200 A VCP = VDD / 2 VCP = VDD / 2 1.0 V < VCP < VDD - 1.0 V VCP = VDD / 2 TA = 25 C Output current magnitude variation vs. voltage 1.0 V < VCP < VDD - 1.0 V TA = 25 C Lock detect outputs: (Cext, LD) VOLC VOHC VOLLD Output voltage LOW, Cext Output voltage HIGH, Cext Output voltage LOW, LD Iout = 0.1 mA Iout = -0.1 mA Iout = 1 mA VDD - 0.4 0.4 0.4 V V V 15 % VDD - 0.4 VDD - 0.4 0.4 V V
Digital test outputs: Dout VOLD VOHD Output voltage LOW Output voltage HIGH 0.4 V V
Charge Pump output: CP ICP - Source ICP -Sink ICPL ICP - Source vs. ICP - Sink ICP vs. VCP Drive current Drive current Leakage current Sink vs. source mismatch -2.6 1.4 -1 2 2 -1.4 2.6 1 25 mA mA A %
(c)2005 Peregrine Semiconductor Corp. All rights reserved. Page 6 of 15
Document No. 70-0140-01 UltraCMOSTM RFIC Solutions
PE9763
Product Specification
Table 6. AC Characteristics
VDD = 3.0 V, -40 C < TA < 85 C, unless otherwise specified
Symbol
fClk tClkH tClkL tDSU tDHLD tPW tCWR tCE tWRC tEC Fin PFin Fin PFin fr Pfr fc N N Note 1: Note 2: Note 3: Note 4:
Parameter
Serial data clock frequency Serial clock HIGH time Serial clock LOW time Sdata set-up time to Sclk rising edge Sdata hold time after Sclk rising edge S_WR pulse width Sclk rising edge to S_WR rising edge Sclk falling edge to E_WR transition S_WR falling edge to Sclk rising edge E_WR transition to Sclk rising edge
Conditions
Control Interface and Latches (see Figures 3, 4) (Note 1)
Min
Typ
Max
10
Units
MHz ns ns ns ns ns ns ns ns ns
30 30 10 10 30 30 30 30 30 275 External AC coupling -5 50 External AC coupling Reference Divider (Note 3) Single ended input Phase Detector (Note 3) 1 kHz Offset 10 kHz Offset -88 -92 -2 50 -5 3200 5 300 5 100
Main Divider (Including Prescaler) (Note 4) Operating frequency Input level range Operating frequency Input level range Operating frequency Reference input power (Note 2) Comparison frequency Phase Noise Phase Noise Main Divider (Prescaler Bypassed) (Note 4) MHz dBm MHz dBm MHz dBc/Hz dBc/Hz MHz dBm
SSB Phase Noise (Fin = 1.9 GHz, fr = 20 MHz, fc = 10 MHz, LBW = 50 kHz, VDD = 3.0 V, Temp = 25 C) (Note 4)
fclk is verified during the functional pattern test. Serial programming sections of the functional pattern are clocked at 10 MHz to verify fclk specification. CMOS logic levels can be used to drive reference input if DC coupled. Voltage input needs to be a minimum of 0.5 Vp-p. For optimum phase noise performance, the reference input falling edge rate should be faster than 80mV/ns. Parameter is guaranteed through characterization only and is not tested. Parameter below are not tested for die sales. These parameters are verified during the element evaluation per the die flow.
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PE9763
Product Specification
Functional Description
The PE9763 consists of counters, a prescaler, an 18-bit delta-sigma modulator (DSM), a phase detector and a charge pump. The dual modulus prescaler divides the VCO frequency by either 10 or 11, depending on the value of the modulus select. Counters "R" and "M" divide the reference and prescaler output, respectively, by integer values stored in a 20-bit register. An additional counter ("A") is used in the modulus select logic.
The DSM modulates the "A" counter outputs in order to achieve the desired fractional step. The phase-frequency detector generates up and down frequency control signals. These signals can be configured to drive a tri-state charge pump. Data is written into the internal registers via the three wire serial bus. There are also various operational and test modes and a lock detect output
Figure 3. Functional Block Diagram
fr
R Counter (6-bit)
fc
R(5:0)
M(8:0)
Sdata Control Pins
Control Logic
K(17:0) A(3:0)
Phase Detector
Charge Pump
Icp
PD_U DSM + Logic PD_D LD Modulus Select
Cext
2 k
Fin Fin
10/11 Prescaler
M Counter (9-bit)
fp
(c)2005 Peregrine Semiconductor Corp. All rights reserved. Page 8 of 15
Document No. 70-0140-01 UltraCMOSTM RFIC Solutions
PE9763
Product Specification
Main Counter Chain
Normal Operating Mode Setting the Pre_en control bit "low" enables the /10/11 prescaler. The main counter chain then divides the RF input frequency (Fin) by an integer or fractional number derived from the values in the "M", "A" counters and the DSM input word K. The accumulator size is 18 bit, so the fractional value is fixed from the ratio K/218. There is an additional bit in the DSM that acts like an extra bit (19th bit). This bit is enabled by asserting the pin RAND_SEL to "high". Enabling this bit has the benefit of reducing the spurious levels. However, a small frequency offset will occur. This positive frequency offset is calculated with the following equation.
foffset = (fr / (R + 1)) / 219 (1)
In this mode, the prescaler and A counter are powered down, and the input VCO frequency is divided by the M counter directly. The following equation relates Fin to the reference frequency fr:
Fin = (M + 1) x (fr / (R+1)) where 1 M 511
(*) Only integer mode
(4)
In frequency bypass mode, neither A counter or K counter is used. Therefore, only integer-N operation is possible.
Reference Counter
The reference counter chain divides the reference frequency fr down to the phase detector comparison frequency fc. The output frequency of the 6-bit R Counter is related to the reference frequency by the following equation:
fc = fr / (R + 1) where 0 R 63 (5)
All of the following equations do not take into account of this frequency offset. If this offset is important to a specific frequency plan, appropriate account needs to be taken. In the normal mode, the output from the main counter chain (fp) is related to the VCO frequency (Fin) by the following equation:
fp = Fin / [10 x (M + 1) + A + K/218] where A M + 1, 1 M 511 (2)
Note that programming R with "0" will pass the reference frequency (fr) directly to the phase detector. Register Programming Serial Interface Mode While the E_WR input is "low" and the S_WR input is "low", serial input data (Sdata input), B0 to B20, are clocked serially into the primary register on the rising edge of Sclk, MSB (B0) first. The LSB is used as address bit. When "0", the contents from the primary register are transferred into the secondary register on the rising edge of either S_WR according to the timing diagrams shown in Figure 4. When "1", data is transferred to the auxiliary register according to the same timing diagram. The secondary register is used to program the various counters, while the auxiliary register is used to program the DSM. Data are transferred to the counters as shown in Table 8 on page 10.
When the loop is locked, Fin is related to the reference frequency (fr) by the following equation:
Fin = [10 x (M + 1) + A + K/218] x (fr / (R+1)) where A M + 1, 1 M 511 (3)
A consequence of the upper limit on A is that Fin must be greater than or equal to 90 x (fr / (R+1)) to obtain contiguous channels. The A counter can accept values as high as 15, but in typical operation it will cycle from 0 to 9 between increments in M. Programming the M counter with the minimum allowed value of "1" will result in a minimum M counter divide ratio of "2". Prescaler Bypass Mode (*) Setting the frequency control register bit Pre_en "high" allows Fin to bypass the /10/11 prescaler.
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PE9763
Product Specification
While the E_WR input is "high" and the S_WR input is "low", serial input data (Sdata input), B0 to B7, are clocked serially into the enhancement register on the rising edge of Sclk, MSB (B0) first. The enhancement register is double buffered to prevent inadvertent control changes during serial loading, with buffer capture of the serially entered data performed on the falling edge of E_WR according to the timing diagram shown in Figure 4. After the falling edge of E_WR, the data provide control bits as shown in Table 9 on page 10 will have their bit functionality enabled by asserting the Enh input "low".
Direct Interface Mode Direct Interface Mode is selected by setting the "Direct" input "high". Counter control bits are set directly at the pins as shown in Table 7 and Table 8.
Table 7. Secondary Register Programming
Interface Mode Direct Serial* Enh 1 1 R5 R5 B0 R4 R4 B1 M8 M8 B2 M7 M7 B3 Pre_en Pre_en B4 M6 M6 B5 M5 M5 B6 M4 M4 B7 M3 M3 B8 M2 M2 B9 M1 M1 B10 M0 M0 B11 R3 R3 B12 R2 R2 B13 R1 R1 B14 R0 R0 B15 A3 A3 B16 A2 A2 B17 A1 A1 B18 A0 A0 B19 Addr X 0
*Serial data clocked serially on Sclk rising edge while E_WR "low" and captured in secondary register on S_WR rising edge.
MSB (first in)
(last in) LSB
Table 8. Auxiliary Register Programming
Interface Mode Direct Serial* Enh 1 1 K17 K17 B0 K16 K16 B1 K15 K15 B2 K14 K14 B3 K13 K13 B4 K12 K12 B5 K11 K11 B6 K10 K10 B7 K9 K9 B8 K8 K8 B9 K7 K7 B10 K6 K6 B11 K5 K5 B12 K4 K4 B13 K3 K3 B14 K2 K2 B15 K1 K1 B16 K0 K0 B17 Rsrv X B18 Rsrv X B19 Addr X 1
*Serial data clocked serially on Sclk rising edge while E_WR "low" and captured in secondary register on S_WR rising edge.
MSB (first in)
(last in) LSB
Table 9. Enhancement Register Programming
Interface Mode Serial* Enh 0 Reserved B0 Reserved B1 fp output B2 Power Down B3 Counter load B4 MSEL output B5 fc output B6 LD Disable B7
*Serial data clocked serially on Sclk rising edge while E_WR "high" and captured in the double buffer on E_WR falling edge.
(last in) LSB MSB (first in)
(c)2005 Peregrine Semiconductor Corp. All rights reserved. Page 10 of 15
Document No. 70-0140-01 UltraCMOSTM RFIC Solutions
PE9763
Product Specification
Figure 4. Serial Interface Mode Timing Diagram
Sdata
E_WR
tEC tCE
Sclk
S_WR
tDSU tDHLD tClkH tClkL tCWR tPW tWRC
Enhancement Register The functions of the enhancement register bits are shown below with all bits active "high".
Table 10. Enhancement Register Bit Functionality
Bit Function
Bit 0 Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 ** Program to 0 Reserve ** Reserve ** fp output Power down Counter load MSEL output fc output LD Disable Reserved. Reserved. Drives the M counter output onto the Dout output. Power down of all functions except programming interface. Immediate and continuous load of counter programming. Drives the internal dual modulus prescaler modulus select (MSEL) onto the Dout output. Drives the reference counter output onto the Dout output. Disables the LD pin for quieter operation.
Description
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PE9763
Product Specification
Phase Detector and Charge Pump The phase detector is triggered by rising edges from the main Counter (fp) and the reference counter (fc). It has two outputs, namely PD_U, and PD_D. If the divided VCO leads the divided reference in phase or frequency (fp leads fc), PD_D pulses "low". If the divided reference leads the divided VCO in phase or frequency (fc leads fp), PD_U pulses "low". The width of either pulse is directly proportional to phase offset between the two input signals, fp and fc. For the UP and DOWN mode, PD_U and PD_D drive an active loop filter which controls the VCO tune voltage. The phase detector gain is equal to VDD / 2 .
PD_U pulses cause an increase in VCO frequency and PD_D pulses cause a decrease in VCO frequency, for a positive Kv VCO. For the charge pump mode, the phase detector outputs are used internally to drive a tri-state charge pump. However, the PD_U, and PD_D output pins will be drive statically to GND. The charge pump will drive a fixed 2 mA of current. A lock detect output, LD is also provided, via the pin Cext. Cext is the logical "NAND" of PD_U and PD_D waveforms, which is driven through a series 2 k resistor. Connecting Cext to an external shunt capacitor provides low pass filtering of this signal. Cext also drives the input of an internal inverting comparator with an open drain output. Thus LD is an "AND" function of PD_U and PD_D.
Figure 5. Typical Phase Noise A typical phase noise plot is shown below. Phase noise results for "Trace 2" is the average values.
Test Conditions: Fout = 1.9202 GHz, Fcomparison = 20 MHz, MASH 1-1, VDD = 3 V, Temp = 25 C, Loop bandwidth = 80 KHz.
(c)2005 Peregrine Semiconductor Corp. All rights reserved. Page 12 of 15
Document No. 70-0140-01 UltraCMOSTM RFIC Solutions
PE9763
Product Specification
Figure 6. Typical Spurious Plot
Test Conditions: Frequency step = 200 KHz, Loop bandwidth = 80 KHz, Fout = 1.9202 GHz, Fcomparison = 20 MHz, MASH 1-1, VDD = 3 V, Temp = 25 C.
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PE9763
Product Specification
Figure 7. Package Drawing
Package dimensions: 68-lead CQFJ
Table 11. Ordering Information
Order Code
9763-01 9763-11 9763-00
Park Marking
PE9763 ES PE9763 PE9763 EK
Description
Engineering Samples Flight Units Evaluation Kit
Packaging
68-lead CQFJ 68-lead CQFJ Tray Tray 1/Box
Shipping Method
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Document No. 70-0140-01 UltraCMOSTM RFIC Solutions
PE9763
Product Specification
Sales Offices
The Americas Peregrine Semiconductor Corporation
9450 Carroll Park Drive San Diego, CA 92121 Tel: 858-731-9400 Fax: 858-731-9499
North Asia Pacific Peregrine Semiconductor K.K.
Teikoku Hotel Tower 10B-6 1-1-1 Uchisaiwai-cho, Chiyoda-ku Tokyo 100-0011 Japan Tel: +81-3-3502-5211 Fax: +81-3-3502-5213
Europe Peregrine Semiconductor Europe
Batiment Maine 13-15 rue des Quatre Vents F-92380 Garches, France Tel: +33-1-47-41-91-73 Fax : +33-1-47-41-91-73
Peregrine Semiconductor, Korea
#B-2402, Kolon Tripolis, #210 Geumgok-dong, Bundang-gu, Seongnam-si Gyeonggi-do, 463-480 S. Korea Tel: +82-31-728-4300 Fax: +82-31-728-4305
South Asia Pacific Peregrine Semiconductor, China
Shanghai, 200040, P.R. China Tel: +86-21-5836-8276 Fax: +86-21-5836-7652
Space and Defense Products
Americas: Tel: 858-731-9453 Europe, Asia Pacific: 180 Rue Jean de Guiramand 13852 Aix-En-Provence Cedex 3, France Tel: +33(0) 4 4239 3361 Fax: +33(0) 4 4239 7227
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Data Sheet Identification
Advance Information
The product is in a formative or design stage. The data sheet contains design target specifications for product development. Specifications and features may change in any manner without notice. The information in this data sheet is believed to be reliable. However, Peregrine assumes no liability for the use of this information. Use shall be entirely at the user's own risk. No patent rights or licenses to any circuits described in this data sheet are implied or granted to any third party. Peregrine's products are not designed or intended for use in devices or systems intended for surgical implant, or in other applications intended to support or sustain life, or in any application in which the failure of the Peregrine product could create a situation in which personal injury or death might occur. Peregrine assumes no liability for damages, including consequential or incidental damages, arising out of the use of its products in such applications. The Peregrine name, logo, and UTSi are registered trademarks and UltraCMOS and HaRP are trademarks of Peregrine Semiconductor Corp.
Preliminary Specification
The data sheet contains preliminary data. Additional data may be added at a later date. Peregrine reserves the right to change specifications at any time without notice in order to supply the best possible product.
Product Specification
The data sheet contains final data. In the event Peregrine decides to change the specifications, Peregrine will notify customers of the intended changes by issuing a DCN (Document Change Notice).
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