UPC3220GR-E1-A - Renesas Electronics

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DESCRIPTION

The

PC3220GR is a silicon monolithic IC designed for use as IF down-converter for digital CATV. This IC

consists of AGC amplifier, mixer and video amplifier.

The package is 16-pin SSOP (Shrink Small Outline Package) suitable for surface mount.

This IC is manufactured using our 10 GHz fT NESAT II AL silicon bipolar process.

This process uses silicon nitride passivation film. This material can protect chip surface from external pollution and

prevent corrosion/migration. Thus, this IC has excellent performance, uniformly and reliability.

FEATURES

• Low distortion IIP3 = +1.0 dBm TYP.

• Wide AGC dynamic range GCRtotal = 45.5 dB TYP.

• On chip video amplifier

• Supply voltage : 5 V

• Packaged in 16-pin SSOP suitable for high-density surface mounting

APPLICATION

• Digital CATV receivers

ORDERING INFORMATION

Part Number Order Number Package Marking Supplying Form

PC3220GR-E1

PC3220GR-E1-A 16-pin plastic SSOP

(5.72 mm (225)) (Pb-Free) Note

C3220 • Embossed tape 12 mm wide

• Pin 1 indicates pull-out direction of tape

• Qty 2.5 kpcs/reel

Note With regards to terminal solder (the solder contains lead) plated products (conventionally plated), contact

your nearby sales office.

Remark To order evaluation samples, contact your nearby sales office.

Part number for sample order:

PC3220GR

DATA SHEET

Caution Observe precautions when handling because these devices are sensitive to electrostatic discharge.

The information in this document is subject to change without notice. Before using this document, please confirm that

this is the latest version.

Not all devices/types available in every country. Please check with local NEC Compound Semiconductor Devices

representative for availability and additional information.

LOW DISTORTION DOWN-CONVERTER IC FOR DIGITAL CATV

BIPOLAR ANALOG INTEGRATED CIRCUIT

PC3220GR

Document No. PU10165EJ05V0DS (5th edition)

Date Published January 2005 CP(K)

Printed in Japan

The mark  shows major revised points.



NEC Compound Semiconductor Devices, Ltd. 2002, 2005

INTERNAL BLOCK DIAGRAM AND PIN CONFIGURATION

(Top View)

RF IN1

RF IN2

VAGC

GND

OSC IN1

OSC IN2

VCC1

VCC2

GND

MIX OUT2

MIX OUT1

AMP IN1

AMP IN2

GND

AMP OUT1

AMP OUT2

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

Data Sheet PU10165EJ05V0DS

PC3220GR

PIN EXPLANATIONS

No. Symbol

Voltage

(V, TYP.)

Explanation Equivalent Circuit

1 RF IN1 1.46

2 RF IN2 1.46

Input pin of IF signal.

1-pin is same phase and 2-pin is opposite phase

at balance input.

In case of single input, 1-pin or 2-pin should be

grounded through capacitor (example 10 nF).

AGC

Control

1 2

3 VAGC 0 to 3.5 Automatic gain control pin.

This pins bias govern the AGC output level.

Minimum gain at VAGC = 0 V

Maximum gain at VAGC = 3.5 V

AGC

Control

4 GND 0.0 Ground pin.

Must be connected to the system ground with

minimum inductance.

Ground pattern on the board should be formed as

wide as possible.



5 OSC IN1 2.6

6 OSC IN2 2.6

Input pin of Oscillator signal.

5-pin is same phase and 6-pin is opposite phase

at balance input.

In case of single input, 5-pin or 6-pin should be

grounded through capacitor (ex. 10 nF).

5 6

7 VCC1 5.0 Power supply pin of IF down convertor block.

Must be connected bypass capacitor to minimize

ground impedance.



8 VCC2 5.0 Power supply pin of video amplifier.

Must be connected bypass capacitor to minimize

ground impedance.



Data Sheet PU10165EJ05V0DS 3

PC3220GR

No. Symbol

Voltage

(V, TYP.)

Explanation Equivalent Circuit

9 AMP

OUT2

2.5

10 AMP

OUT1

2.5

Output pin of video amplifier.

OUT1 and IN1 are same phase.

OUT2 and IN2 are same phase.

11 GND 0.0 Ground pin.

Must be connected to the system ground with

minimum inductance.

Ground pattern on the board should be formed as

wide as possible.



12 AMP IN2 1.45

13 AMP IN1 1.45

Signal input pin of video amplifier.

This pin is high impedance.

12 13

14 GND 0.0 Ground pin.

Must be connected to the system ground with

minimum inductance.

Ground pattern on the board should be formed as

wide as possible.



15 MIX OUT1 3.7

16 MIX OUT2 3.7

Output pin of mixer.

This output pin features low-impedance because

of its emitter-follower output port.

Data Sheet PU10165EJ05V0DS

PC3220GR

ABSOLUTE MAXIMUM RATINGS

Parameter Symbol Conditions Ratings Unit

Supply Voltage VCC TA = +25°C 6.0 V

Power Dissipation PD TA = +85°C Note 433 mW

Operating Ambient Temperature TA −40 to +85 °C

Storage Temperature Tstg −55 to +150 °C

Note Mounted on double-sided copper-clad 50 × 50 × 1.6 mm epoxy glass PWB

RECOMMENDED OPERATING RENGE

Parameter Symbol Conditions MIN. TYP. MAX. Unit

Supply Voltage VCC 4.5 5.0 5.5 V

Operating Ambient Temperature TA VCC = 4.5 to 5.5 V −40 +25 +85 °C

Gain Control Voltage Range VAGC 0 − VCC V

Data Sheet PU10165EJ05V0DS 5

PC3220GR

ELECTRICAL CHARACTERISTICS (TA = +25°C, VCC = 5 V)

Parameter Symbol Test Conditions MIN. TYP. MAX. Unit

DC Characteristics

Circuit Current 1

(Total Block)

ICC1 No input signal, VCC1 = VCC2 = 5 V

Note 4

33.0 42.0 53.5 mA

Circuit Current 2

(AGC Amplifier Block + Mixer Block)

ICC2 No input signal, VCC1 = 5 V Note 4 15.0 20.0 25.5 mA

Circuit Current 3

(Video Amplifier Block)

ICC3 No input signal, VCC2 = 5 V Note 4 18.0 22.0 28.0 mA

AGC Voltage High Level VAGC (H) @ Maximum gain Note 1 3.0 − VCC V

AGC Voltage Low Level VAGC (L) @ Minimum gain Note 1 0 − 0.5 V

RF Characteristics

(AGC Amplifier Block + Mixer Block: fRF = 84 MHz, fLO = 134 MHz, PLO = −15 dBm, fIF = 50 MHz, ZS = 50 Ω, ZL = 1 kΩ)

RF Input Frequency Range fRF fIF = 50 MHz constant Note 1 30 − 250 MHz

IF Output Frequency Range fIF fRF = 84 MHz constant Note 1 0.1 − 150 MHz

Maximum Conversion Gain CGMAX VAGC = 3.0 V, Pin = −50 dBm Note 1 30.5 33.0 35.5 dB

Minimum Conversion Gain CGMIN VAGC = 0.5 V, Pin = −20 dBm Note 1 −18.0 −12.5 −3.5 dB

AGC Dynamic Range GCRAGC VAGC = 0.5 to 3.0 V Note 1 36.0 45.5 − dB

Noise Figure NF DSB, VAGC = 3.0 V (@ Maximum gain)

Note 2

− 7.0 8.5 dB

3rd Order Intermodulaion Distortion IM3 Vout = 0.236 Vp-p × 2 tone,

(single-ended output),

Pin −30 dBm/tone

fRF1 = 84 MHz, fRF2 = 85 MHz Note 1

24.0 26.5 − dBc

RF Characteristics (Video Amplifier Block: f = 50 MHz, ZS = 50 Ω, ZL = 1 kΩ)

Differential Gain Gdiff Pin = −55 dBm Note 3 48.0 50.5 53.5 dB

Maximum Output Voltage 2 Voclip2 Pin = −25 dBm Note 3 2.95 3.70 − Vp-p

Notes 1. By measurement circuit 1

2. By measurement circuit 2

3. By measurement circuit 4

4. By measurement circuit 6

Data Sheet PU10165EJ05V0DS

PC3220GR

STANDARD CHARACTERISTICS (TA = +25°C, VCC = 5 V, ZS = 50 Ω)

Parameter Symbol Test Conditions Reference Value Unit

AGC Amplifier Block + Mixer Block (fRF = 84 MHz, fLO = 134 MHz, PLO = −15 dBm, fIF = 50 MHz, ZS = 50 Ω, ZL = 1 kΩ)

Input 3rd Order Distortion

Intercept Point

IIP3 VAGC = 0.5 V (@ Minimum gain)

fRF1 = 84 MHz, fRF2 = 85 MHz Note 1

+1.0 dBm

Maximum Output Voltage1 Voclip1 VAGC = 3.0 V, Pin = −20 dBm Note 1 0.65 Vp-p

RF IN Impedance ZRFin VAGC = 3.0 V, f = 84 MHz Note 2 440 − j1100 Ω

OSC IN Impedance ZOSCin VAGC = 3.0 V, f = 134 MHz Note 2 280 − j810 Ω

MIXER OUT Impedance ZMIXout VAGC = 3.0 V, f = 50 MHz Note 2 30.2 + j2.5 Ω

Video Amplifier Block (f = 50 MHz, ZS = 50 Ω, ZL = 1 kΩ)

Frequency Range fBW Pin = −55 dBm, G (f = 10 MHz) −1 dB

Note 3

60 MHz

Input Impedance ZAMPin f = 50 MHz Note 4 330 − j480 Ω

Output Impedance ZAMPout f = 50 MHz Note 4 21.9 + j22.6 Ω

3rd Order Intermodulaion Distortion IM3 Vout = 0.7 Vp-p × 2 tone,

fin1 = 49 MHz, fin2 = 50 MHz Note 3

55.0 dBc

Total Block (fRF = 84 MHz, fLO = 134 MHz, PLO = −15 dBm, fIF = 50 MHz, ZS = 50 Ω, ZL = 1 kΩ)

Maximum Conversion Gain CGMAX VAGC = 3.0 V, Pin = −70 dBm Note 5 67.5 dB

Minimum Conversion Gain CGMIN VAGC = 0.5 V, Pin = −40 dBm Note 5 22.0 dB

Total Dynamic Range GCR VAGC = 0.5 to 3.0 V Note 5 45.5 dB

Noise Figure NF DSB, VAGC = 3.0 V (@ Maximum gain)

Note 6

7.0 dB

Maximum Output Voltage Voclip VAGC = 3.0 V (@ Minimum gain)

Note 5

3.7 Vp-p

Input 3rd Order Distortion

Intercept Point

IIP3total VAGC = 0.5 V (@ Minimum gain)

fRF1 = 84 MHz, fRF2 = 85 MHz Note 5

+1.0 dBm

3rd Order Intermodulaion Distortion IM3total Vout = 0.7 Vp-p × 2 tone,

Pin −40 dBm/tone

fRF1 = 84 MHz, fRF2 = 85 MHz Note 5

51.0 dBc

Notes 1. By measurement circuit 1

2. By measurement circuit 3

3. By measurement circuit 4

4. By measurement circuit 5

5. By measurement circuit 6

6. By measurement circuit 7

Data Sheet PU10165EJ05V0DS 7

PC3220GR

MEASUREMENT CIRCUIT 1

Note

Spectrum

Analyzer

50 Ω

51 Ω

1 kΩ

50 Ω

RF1

VAGC

VCC1

RF2

50 Ω

1 F

1 kΩ

1 F

0.1 F

0.1 F//20 pF

0.1 F

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

Note Balun Transformer : TOKO 617DB-1010 B4F (Double balanced type)

MEASUREMENT CIRCUIT 2

Note

51 Ω

1 kΩ

50 Ω

AGC

1 F

1 kΩ

1 F

0.1 F

0.1 F//20 pF

0.1 F

50 Ω

Noise Source

0.1 F

Noise Figure Meter

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

0.1 F

Note Balun Transformer : TOKO 617DB-1010 B4F (Double balanced type)

Data Sheet PU10165EJ05V0DS

PC3220GR

MEASUREMENT CIRCUIT 3

51 Ω

RF IF

AGC

1 F

0.1 F

0.1 F//20 pF

0.1 F

50 Ω50 Ω

LO Port Input Impedance IF Port Input Impedance

RF Port Input Impedance

Network Analyzer

0.1 F

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

MEASUREMENT CIRCUIT 4

21 F

1 F

50 Ω

51 Ω

1 kΩ

51 Ω50 Ω

51 Ω

Spectrum

Analyzer

Vin

Vout

VOUT

0.1 F

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

Remarks 1. Voltage Gain (Single Ended) = 20 log (VOUT/Vin) (dB)

2. Differential Gain (Differential-out) = 20 log (2 × VOUT/Vin) (dB)

3. VOUT = Vout (Measured Value) × (1 050/50)

Data Sheet PU10165EJ05V0DS 9

PC3220GR

MEASUREMENT CIRCUIT 5

VCC21 F

1 F

50 Ω

51 Ω

0.1 F

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

Output Impedance

Input Impedance

Network

Analyzer

MEASUREMENT CIRCUIT 6

Note

Spectrum

Analyzer

50 Ω

51 Ω

1 kΩ

50 Ω

AGC

1 F

1 kΩ

1 F

0.1 F

2 1 F

0.1 F

0.1 F//20 pF

0.1 F

Loss 10 dB

@50 MHz

0.1 F

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

Note Balun Transformer : TOKO 617DB-1010 B4F (Double balanced type)

Data Sheet PU10165EJ05V0DS

PC3220GR

MEASUREMENT CIRCUIT 7

Note

51 Ω

1 kΩ

50 Ω

AGC

1 F

1 kΩ

1 F

0.1 F

2 1 F

0.1 F

0.1 F//20 pF

0.1 F

RF 0.1 F

50 Ω

Noise Figure Meter

Noise Source

0.1 F

Video Amp.

AGC Amp. Mixer

OSC OUT

Buffer Amp.

Note Balun Transformer : TOKO 617DB-1010 B4F (Double balanced type)

The application circuits and their parameters are for reference only and are not intended for use in actual design-ins.

Data Sheet PU10165EJ05V0DS 11

PC3220GR

ILLUSTRATION OF THE MEASUREMENT CIRCUIT1, 2 ASSEMBLED ON EVALUATION BOARD

PC3220GR

Note

1 kΩ

51 Ω

1 F

0.1 F

20 pF

0.1 F

1 F

0.1 F

1 F

0.1 F

AGC

RF1, RF2

out

1 (AGC + MIX)

Note Balun Transformer

Remarks

1. Back side: GND pattern

2. Solder plated on pattern

3. : Through hole

4. : Represents cutout

Data Sheet PU10165EJ05V0DS

PC3220GR

ILLUSTRATION OF THE MEASUREMENT CIRCUIT3 ASSEMBLED ON EVALUATION BOARD

PC3220GR

51 Ω

1 F

0.1 F

20 pF

0.1 F

1 F

0.1 F

1 F

0.1 F

AGC

out

1 (AGC + MIX)

1 F

Remarks

1. Back side: GND pattern

2. Solder plated on pattern

3. : Through hole

4. : Represents cutout

5. : Represents short-circuit strip

Data Sheet PU10165EJ05V0DS 13

PC3220GR

ILLUSTRATION OF THE MEASUREMENT CIRCUIT4 ASSEMBLED ON EVALUATION BOARD

PC3220GR

1 kΩ

1 F

1 kΩ

1 F

51 Ω

0.1 F

1 F

2 (Video)

Vout

Vin

51 Ω

Remarks

1. Back side: GND pattern

2. Solder plated on pattern

3. : Through hole

4. : Represents short-circuit strip

Data Sheet PU10165EJ05V0DS

PC3220GR

ILLUSTRATION OF THE MEASUREMENT CIRCUIT5 ASSEMBLED ON EVALUATION BOARD

PC3220GR

1 F

0.1 F

1 F

2 (Video)

Input Impedance Output Impedance

51 Ω

Remarks

1. Back side: GND pattern

2. Solder plated on pattern

3. : Through hole

4. : Represents short-circuit strip

Data Sheet PU10165EJ05V0DS 15

PC3220GR

ILLUSTRATION OF THE MEASUREMENT CIRCUIT6, 7 ASSEMBLED ON EVALUATION BOARD

PC3220GR

Note

1 kΩ

1 F

1 kΩ

1 F

1 kΩ

0.1 F

20 pF

0.1 F

1 F

0.1 F

1 F

0.1 F

1 F

AGC

1 (VGC + MIX)

2 (Video)

Vout

51 Ω

Note Balun Transformer

Remarks

1. Back side: GND pattern

2. Solder plated on pattern

3. : Through hole

4. : Represents cutout

5. : Represents short-circuit strip

Data Sheet PU10165EJ05V0DS

PC3220GR

TYPICAL CHARACTERISTICS (TA = +25°C , unless otherwise specified)

CIRCUIT CURRENT1 (TOTAL BLOCK)

vs. SUPPLY VOLTAGE

Circuit Current1 (Total Block) I

1 (mA)

Supply Voltage V

1, 2 (V)

0123456

AGC

= 0 V

No Singnal

Measurement

Cuicuit6

= –40°C

= +25°C

= +85°C

CIRCUIT CURRENT2 (AGC AMPLIFIER

+ MIXER BLOCK) vs. SUPPLY VOLTAGE

Circuit Current2 (AGC Amplifier + Mixer Block) I

2 (mA)

Supply Voltage V

1 (V)

0123456

= –40°C

= +85°C

= +25°C

CIRCUIT CURRENT3 (VIDEO AMPLIFIER

BLOCK) vs. SUPPLY VOLTAGE

Circuit Current3 (Video Amplifier Block) I

3 (mA)

Supply Voltage V

2 (V)

0123456

= –40°C

= +85°C

= +25°C

2 = V

AGC

= 0 V

No Singnal

Measurement

Cuicuit6

1 = V

AGC

= 0 V

No Singnal

Measurement

Cuicuit6

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS 17

PC3220GR

−AGC Amplifier Block + Mixer Block−

VOLTAGE GAIN vs.

RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

–20

RF Input Frequency Range f

(MHz)

0 50 100 150 200 250

= –40°C

= +85°C

= +25°C

VOLTAGE GAIN vs.

RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

RF Input Frequency Range f

(MHz)

0 50 100 150 200 250

1 = 5.5 V

5.0 V

4.5 V

VOLTAGE GAIN vs.

RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

RF Input Frequency Range f

(MHz)

0 50 100 150 200 250

1 = 5.5 V

5.0 V

4.5 V

AGC

= 1.5 V

= –50 dBm

60 to 290 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

AGC

= 3.0 V

= –50 dBm

60 to 290 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

AGC

= 1.5 V

= 5.0 V

= –50 dBm

60 to 290 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

VOLTAGE GAIN vs.

RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

RF Input Frequency Range f

(MHz)

0 50 100 150 200 250

AGC

= 0.5 V

= –20 dBm

60 to 290 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

1 = 4.5 V

5.0 V

5.5 V

VOLTAGE GAIN vs.

RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

–20

RF Input Frequency Range f

(MHz)

0 50 100 150 200 250

= –40°C

= +85°C

= +25°C

AGC

= 3.0 V

= 5.0 V

= –50 dBm

60 to 290 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

VOLTAGE GAIN vs.

RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

–20

RF Input Frequency Range f

(MHz)

0 50 100 150 200 250

= –40°C

= +85°C

= +25°C

AGC

= 0.5 V

= 5.0 V

= –20 dBm

60 to 290 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS

PC3220GR

VOLTAGE GAIN vs.

IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

–20

IF Output Frequency Range fIF (MHz)

020 60

80 140 160

VOLTAGE GAIN vs.

IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

–20

IF Output Frequency Range fIF (MHz)

02040 100 140 160

TA = +25°C

VOLTAGE GAIN vs.

IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

–20

IF Output Frequency Range fIF (MHz)

020 60 120 140 160

12060 80

TA = –40°C

100

8040

TA = –40°C

TA = +25°C

TA = +85°C

40 100 120

TA = +85°CTA = +25°C

TA = –40°C

VOLTAGE GAIN vs.

IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

IF Output Frequency Range fIF (MHz)

020 60 100 140 160

40 80 120

VCC1 = 5.5 V

5.0 V

4.5 V

VOLTAGE GAIN vs.

IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

IF Output Frequency Range fIF (MHz)

020 60 100 140 160

40 80 120

VCC1 = 4.5 V

5.0 V

5.5 V

VOLTAGE GAIN vs.

IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

–5

–10

–15

IF Output Frequency Range fIF (MHz)

020 60 100 140 160

40 80 120

VCC1 = 4.5 V

5.0 V

5.5 V

VAGC = 0.5 V

Pin = –20 dBm

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

Measurement Cuicuit1

VAGC = 1.5 V

Pin = –50 dBm

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

Measurement Cuicuit1

VAGC = 3.0 V

Pin = –50 dBm

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

Measurement Cuicuit1

VAGC = 0.5 V

VCC1 = 5.0 V

Pin = –20 dBm

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

Measurement Cuicuit1

VAGC = 1.5 V

VCC1 = 5.0 V

Pin = –50 dBm

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

Measurement Cuicuit1

VAGC = 3.0 V

VCC1 = 5.0 V

Pin = –50 dBm

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

Measurement Cuicuit1

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS 19

PC3220GR

VOLTAGE GAIN vs.

GAIN CONTROL VOLTAGE RANGE

Voltage Gain (dB)

–5

–10

–15

–20

Gain Control Voltage Range V

AGC

(V)

0 0.5 1.5 3.0 3.5

= 84 MHz

= –50 dBm

= 134 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

1.0 2.0 2.5

1 = 4.5 V

5.0 V

5.5 V

VOLTAGE GAIN vs.

GAIN CONTROL VOLTAGE RANGE

Voltage Gain (dB)

–5

–10

–15

–20

Gain Control Voltage Range V

AGC

(V)

0 0.5 1.5 3.0 3.5

1.0 2.0 2.5

= –40°C

+25°C

+85°C

NOISE FIGURE vs.

GAIN CONTROL VOLTAGE RANGE

Noise Figure NF (dB)

Gain Control Voltage Range V

AGC

(V)

1.0 1.5 3.0 3.5

2.0 2.5

1 = 5.5 V

5.0 V

4.5 V

= 134 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit2

NOISE FIGURE vs.

GAIN CONTROL VOLTAGE RANGE

Noise Figure NF (dB)

Gain Control Voltage Range V

AGC

(V)

1.0 1.5 3.0 3.5

2.0 2.5

= +85°C

+25°C

–40°C

1 = 5.0 V

= 84 MHz

= –50 dBm

= 134 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit1

1 = 5.0 V

= 134 MHz

= –15 dBm

= 50 MHz

Measurement Cuicuit2

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS

PC3220GR

OUTPUT POWER vs. INPUT POWER

Output Power P

out

(50 Ω/1 050 Ω) (dBm)

–15

–20

–25

–30

–35

–40

–45

–50

–55

Input Power Pin (dBm)

–55 –50 –40 –20 –15

–45 –30 –25

VCC1 = 5.5 V

5.0 V

4.5 V

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–100

–60 –50 –20

–40 –30

VAGC = 3.0 V

fRF1 = 84 MHz

fRF2 = 85 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50, 49 MHz

Measurement Cuicuit1

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–35

OUTPUT POWER vs. INPUT POWER

Output Power P

out

(50 Ω/1 050 Ω) (dBm)

–15

–20

–25

–30

–35

–40

–45

–50

–55

Input Power Pin (dBm)

–55 –50 –40 –20 –15

–45 –30 –25

TA = +25°C

–35

–40°C

+85°C

VAGC = 3.0 V

fRF

84 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50 MHz

Measurement Cuicuit1

VCC1 = 4.5 V

5.0 V

5.5 V

–20

–30

–40

–50

–60

–70

–80

–90

–100

–60 –50 –20

–40 –30

TA = –40°C

+25°C

+85°C

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–100

–50 –40 –10

–30 –20

VAGC = 2.1 V

fRF1 = 84 MHz

fRF2 = 85 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50, 49 MHz

Measurement Cuicuit1

VCC1 = 4.5 V

5.0 V

5.5 V

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–100

–50 –40 –10

–30 –20

VCC1 = 5.0 V

VAGC = 3.0 V

fRF

84 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50 MHz

Measurement Cuicuit1

VCC1 = 5.0 V

VAGC = 3.0 V

fRF1 = 84 MHz

fRF2 = 85 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50, 49 MHz

Measurement Cuicuit1

TA = –40°C

+25°C

+85°C

VCC1 = 5.0 V

VAGC = 2.1 V

fRF1 = 84 MHz

fRF2 = 85 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50, 49 MHz

Measurement Cuicuit1

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS 21

PC3220GR

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–100

–30 –20 10

–10 0

AGC

= 0.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit1

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

1 = 4.5 V

5.0 V

5.5 V

–20

–30

–40

–50

–60

–70

–80

–90

–100

–30 –20 10

–10 0

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–100

–30 –20 10

–10 0

AGC

= 1.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit1

1 = 4.5 V

5.0 V

5.5 V

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–100

–30 –20 10

–10 0

= –40°C

+25°C

+85°C

1 = 5.0 V

AGC

= 1.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit1

= –40°C

+25°C

+85°C

1 = 5.0 V

AGC

= 0.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit1

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS

PC3220GR

−Video Amplifier Block−

VOLTAGE GAIN (SINGLE-ENDED)

vs. INPUT FREQUENCY

Voltage Gain (Single-ended) (dB)

Input Frequency fin (MHz)

10 100

VCC2 = 4.5 V

5.0 V

5.5 V

VOLTAGE GAIN (SINGLE-ENDED)

vs. INPUT FREQUENCY

Voltage Gain (Single-ended) (dB)

Input Frequency fin (MHz)

10 100

TA = –40°C

+25°C

+85°C

VCC2 = 5 V

–55 dBm

Measurement Cuicuit4

OUTPUT POWER vs. INPUT POWER

Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–5

–10

–15

–20

–25

–30

–35

–40

–50 –45 –15

–25 –20

fIF = 50 MHz

Measurement Cuicuit4

VCC2 = 4.5 V

5.0 V

5.5 V

–40 –35 –30

OUTPUT POWER vs. INPUT POWER

Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–5

–10

–15

–20

–25

–30

–35

–40

–50 –45 –15

–25 –20

VCC2 = 5 V

fIF = 50 MHz

Measurement Cuicuit4

TA = –40°C

+25°C

+85°C

–40 –35 –30

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–90

–60 –20

–30

fIF1 = 50 MHz

fIF2 = 49 MHz

Measurement Cuicuit4

VCC2 = 4.5 V

5.0 V

5.5 V

–50 –40

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–90

–60 –20

–30

VCC2 = 5 V

fIF1 = 50 MHz

fIF2 = 49 MHz

Measurement Cuicuit4

TA = –40°C

+25°C

+85°C

–50 –40

–55 dBm

Measurement Cuicuit4

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS 23

PC3220GR

−Total Block−

VOLTAGE GAIN

vs. RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

RF Input Frequency Range fRF (MHz)

00 250

VCC1, 2 = 4.5 V

5.0 V

5.5 V

100 150 200

VOLTAGE GAIN

vs. RF INPUT FREQUENCY RANGE

Voltage Gain (dB)

RF Input Frequency Range fRF (MHz)

00 250

TA = –40°C

+25°C

+85°C

100 150 200

VCC1, 2 = 5 V

fLO =

60 to 290 MHz

VAGC = 3.0 V (Pin = –70 dBm)

VAGC = 1.5 V (Pin = –40 dBm)

VAGC = 0.5 V (Pin = –40 dBm)

VAGC = 3.0 V (Pin = –70 dBm)

VAGC = 1.5 V (Pin = –40 dBm)

VAGC = 0.5 V (Pin = –40 dBm)

VOLTAGE GAIN

vs. IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

IF Output Frequency Range fIF (MHz)

100 160

VCC1, 2 = 4.5 V

5.0 V

5.5 V

100 120 140

VOLTAGE GAIN

vs. IF OUTPUT FREQUENCY RANGE

Voltage Gain (dB)

IF Output Frequency Range fIF (MHz)

00 160

TA = –40°C

+25°C

+85°C

60 100 140

VCC1, 2 = 5 V

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

VAGC = 3.0 V (Pin = –70 dBm)

VAGC = 1.5 V (Pin = –40 dBm)

VAGC = 0.5 V (Pin = –40 dBm)

VAGC = 3.0 V (Pin = –70 dBm)

VAGC = 1.5 V (Pin = –40 dBm)

VAGC = 0.5 V (Pin = –40 dBm)

40 60 80

VOLTAGE GAIN

vs. GAIN CONTROL VOLTAGE RANGE

Voltage Gain (dB)

Gain Control Voltage Range VAGC (V)

0 0.5 1.5 3.0 3.5

fRF

84 MHz

Pin = –70 dBm

fLO = 134 MHz

PLO = –15 dBm

Measurement Cuicuit6

1.0 2.0 2.5

VCC1, 2 = 4.5 V

5.0 V

5.5 V

Voltage Gain (dB)

Gain Control Voltage Range VAGC (V)

0 0.5 1.5 3.0 3.5

VCC1, 2 = 5 V

fRF

84 MHz

Pin = –70 dBm

fLO = 134 MHz

PLO = –15 dBm

Measurement Cuicuit6

1.0 2.0 2.5

TA = –40°C

+25°C

+85°C

40 80 120

fLO =

60 to 290 MHz

PLO = –15 dBm

fIF = 50 MHz

Measurement Cuicuit6

PLO = –15 dBm

fIF = 50 MHz

Measurement Cuicuit6

fLO =

94 to 234 MHz

PLO = –15 dBm

fRF = 84 MHz

Measurement Cuicuit6

VOLTAGE GAIN

vs. GAIN CONTROL VOLTAGE RANGE

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS

PC3220GR

NOISE FIGURE vs.

GAIN CONTROL VOLTAGE RANGE

Noise Figure NF (dB)

Gain Control Voltage Range VAGC (V)

1.0 1.5 3.0 3.5

fIF

50 MHz

fLO = 134 MHz

PLO = –15 dBm

Measurement Cuicuit7

2.0 2.5

VCC1, 2 = 4.5 V

5.0 V

5.5 V

NOISE FIGURE vs.

GAIN CONTROL VOLTAGE RANGE

Noise Figure NF (dB)

Gain Control Voltage Range VAGC (V)

1.0 1.5 3.0 3.5

VCC1, 2 =

5 V

fIF

50 MHz

fLO = 134 MHz

PLO = –15 dBm

Measurement Cuicuit7

2.0 2.5

TA = –40°C

+25°C

+85°C

OUTPUT POWER vs. INPUT POWER

Output Power P

out

(50 Ω/1 050 Ω) (dBm)

–5

–10

–15

–20

–25

–30

–35

–40

Input Power Pin (dBm)

–75 –70 –60 –40 –35

–65 –50 –45

VCC1, 2 = 5.5 V

5.0 V

4.5 V

–55

VAGC = 3.0 V

fRF

84 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50 MHz

Measurement Cuicuit6

OUTPUT POWER vs. INPUT POWER

Output Power P

out

(50 Ω/1 050 Ω) (dBm)

–5

–10

–15

–20

–25

–30

–35

–40

Input Power Pin (dBm)

–75 –70 –60 –40 –35

–65 –50 –45

TA = +25°C

–55

–40°C

+85°C

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–80 –70 –40

–60 –50

VAGC = 3.0 V

fRF1 = 84 MHz

fRF2 = 85 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50, 49 MHz

Measurement Cuicuit6

VCC1, 2 = 4.5 V

5.0 V

5.5 V

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power P

out

(50 Ω/1 050 Ω) (dBm)

Input Power Pin (dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–80 –70 –40

–60 –50

VCC1, 2 = 5.0 V

VAGC = 3.0 V

fRF1 = 84 MHz

fRF2 = 85 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50, 49 MHz

Measurement Cuicuit6

TA = –40°C

+25°C

+85°C

VCC1, 2 = 5.0 V

VAGC = 3.0 V

fRF

84 MHz

fLO = 134 MHz

PLO = –15 dBm

fIF = 50 MHz

Measurement Cuicuit6

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS 25

PC3220GR

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power Pout (50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–50 –40 –10

–30 –20

AGC

= 1.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit6

1, 2 = 4.5 V

5.0 V

5.5 V

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power Pout (50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–50 –40 –10

–30 –20

1, 2 = 5 V

AGC

= 1.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit6

= –40°C

+25°C

+85°C

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power Pout (50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–35 –25 5

–15 –5

AGC

= 0.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit6

1, 2 = 4.5 V

5.0 V

5.5 V

2 TONE OUTPUT POWER

vs. INPUT POWER

2 tone Output Power Pout (50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–10

–20

–30

–40

–50

–60

–70

–80

–35 –25 5

–15 –5

1, 2 = 5.0 V

AGC

= 0.5 V

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

Measurement Cuicuit6

= –40°C

+25°C

+85°C

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS

PC3220GR

, 2 TONE OUTPUT POWER,

GAIN CONTROL VOLTAGE vs. INPUT POWER

2 tone Output Power Pout (50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–80 –60 0

–40 –20

Conditions

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

out

= 0.7 V

p-p

/tone

Measurement Cuicuit6

1, 2 = 4.5 V

5.0 V

5.5 V

Gain Control Voltage Range V

AGC

(V)

–70 –50 –30 –10

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

, 2 TONE OUTPUT POWER,

GAIN CONTROL VOLTAGE vs. INPUT POWER

2 tone Output Power Pout (50 Ω/1 050 Ω) (dBm)

Input Power P

(dBm)

–20

–30

–40

–50

–60

–70

–80

–90

–80 –60 0

–40 –20

= –40°C

+25°C

+85°C

–70 –50 –30 –10

Gain Control Voltage Range V

AGC

(V)

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

AGC

out

3rd Order Intermoduration Distortion IM

(dBc)

3rd Order Intermoduration Distortion IM

(dBc)

AGC

out

Conditions

1 = 84 MHz

2 = 85 MHz

= 134 MHz

= –15 dBm

= 50, 49 MHz

out

= 0.7 V

p-p

/tone

Measurement Cuicuit6

Remark The graphs indicate nominal characteristics.

Data Sheet PU10165EJ05V0DS 27

PC3220GR

S-PARAMETERS

−AGC Amplifier Block + Mixer Block− (VCC1 = 5.0 V, VAGC = 3.0 V, by measurement circuit 3)

MIXER RF Input Impedance

1 : 30 MHz 1.830 kΩ–1.603 kΩ3.309 pF

2 : 84 MHz 443.0 Ω–1.096 kΩ1.730 pF

3 : 150 MHz 207.4 Ω–728.7 Ω1.456 pF

4 : 250 MHz 109.7 Ω–454.1 Ω1.402 pF

MIXER IF Output Impedance

1 : 10 MHz 29.48 Ω634.6 mΩ10.07 nH

2 : 36 MHz 29.98 Ω1.908 Ω8.431 nH

3 : 50 MHz 30.17 Ω2.476 Ω7.884 nH

4 : 100 MHz 30.79 Ω4.171 Ω6.638 nH

Data Sheet PU10165EJ05V0DS

PC3220GR

MIXER OSC Input Impedance

Data Sheet PU10165EJ05V0DS 29

PC3220GR

1 : 30 MHz 1.820 kΩ–1.823 kΩ2.911 pF

2 : 100 MHz 415.5 Ω–1.010 Ω1.575 pF

3 : 134 MHz 284.6 Ω–813.1 Ω1.461 pF

4 : 250 MHz 133.4 Ω–487.0 Ω1.307 pF

−Video Amplifier Block− (VCC2 = 5.0 V, by measurement circuit 5)

Video Amplifier Input Impedance

1 : 10 MHz 1.187 kΩ–1.177 kΩ13.54 pF

2 : 36 MHz 389.8 Ω–588.3 Ω7.516 pF

3 : 50 MHz 333.4 Ω–481.1 Ω6.617 pF

4 : 100 MHz 245.5 Ω–369.7 Ω4.304 pF

Video Amplifier Output Impedance

1 : 10 MHz 10.04 Ω5.225 Ω83.16 nH

2 : 36 MHz 15.86 Ω17.70 Ω78.25 nH

3 : 50 MHz 21.54 Ω22.61 Ω71.96 nH

4 : 100 MHz 45.48 Ω23.89 Ω38.02 nH

Data Sheet PU10165EJ05V0DS

PC3220GR

PACKAGE DIMENSIONS

16-PIN PLASTIC SSOP (5.72 mm (225)) (UNIT: mm)

detail of lead end

5˚± 5˚

16 9

5.2±0.3

6.4±0.2

4.4±0.2

0.5±0.2

1.0±0.2

0.17

+0.08

–0.07

0.10 S

1.8 MAX.

1.5±0.1

0.475 MAX.

0.22

+0.10

–0.05

0.125±0.075

0.10 M

0.65

Data Sheet PU10165EJ05V0DS 31

PC3220GR

NOTES ON CORRECT USE

(1) Observe precautions for handling because of electro-static sensitive devices.

(2) Form a ground pattern as widely as possible to minimize ground impedance (to prevent undesired oscillation).

All the ground pins must be connected together with wide ground pattern to decrease impedance difference.

(3) The bypass capacitor should be attached to VCC line.

RECOMMENDED SOLDERING CONDITIONS

This product should be soldered and mounted under the following recommended conditions. For soldering

methods and conditions other than those recommended below, contact your nearby sales office.

Soldering Method Soldering Conditions Condition Symbol

Infrared Reflow Peak temperature (package surface temperature) : 260°C or below

Time at peak temperature : 10 seconds or less

Time at temperature of 220°C or higher : 60 seconds or less

Preheating time at 120 to 180°C : 120±30 seconds

Maximum number of reflow processes : 3 times

Maximum chlorine content of rosin flux (% mass) : 0.2%(Wt.) or below

IR260

Wave Soldering Peak temperature (molten solder temperature) : 260°C or below

Time at peak temperature : 10 seconds or less

Preheating temperature (package surface temperature) : 120°C or below

Maximum number of flow processes : 1 time

Maximum chlorine content of rosin flux (% mass) : 0.2%(Wt.) or below

WS260

Partial Heating Peak temperature (pin temperature) : 350°C or below

Soldering time (per side of device) : 3 seconds or less

Maximum chlorine content of rosin flux (% mass) : 0.2%(Wt.) or below

HS350

Caution Do not use different soldering methods together (except for partial heating).

Data Sheet PU10165EJ05V0DS

PC3220GR

When the product(s) listed in this document is subject to any applicable import or export control laws and regulation of the authority

having competent jurisdiction, such product(s) shall not be imported or exported without obtaining the import or export license.

M8E 00. 4 - 0110

The information in this document is current as of January, 2005. The information is subject to

change without notice. For actual design-in, refer to the latest publications of NEC's data sheets or

data books, etc., for the most up-to-date specifications of NEC semiconductor products. Not all

products and/or types are available in every country. Please check with an NEC sales representative

for availability and additional information.

No part of this document may be copied or reproduced in any form or by any means without prior

written consent of NEC. NEC assumes no responsibility for any errors that may appear in this document.

NEC does not assume any liability for infringement of patents, copyrights or other intellectual property rights of

third parties by or arising from the use of NEC semiconductor products listed in this document or any other

liability arising from the use of such products. No license, express, implied or otherwise, is granted under any

patents, copyrights or other intellectual property rights of NEC or others.

Descriptions of circuits, software and other related information in this document are provided for illustrative

purposes in semiconductor product operation and application examples. The incorporation of these

circuits, software and information in the design of customer's equipment shall be done under the full

responsibility of customer. NEC assumes no responsibility for any losses incurred by customers or third

parties arising from the use of these circuits, software and information.

While NEC endeavours to enhance the quality, reliability and safety of NEC semiconductor products, customers

agree and acknowledge that the possibility of defects thereof cannot be eliminated entirely. To minimize

risks of damage to property or injury (including death) to persons arising from defects in NEC

semiconductor products, customers must incorporate sufficient safety measures in their design, such as

redundancy, fire-containment, and anti-failure features.

NEC semiconductor products are classified into the following three quality grades:

"Standard", "Special" and "Specific". The "Specific" quality grade applies only to semiconductor products

developed based on a customer-designated "quality assurance program" for a specific application. The

recommended applications of a semiconductor product depend on its quality grade, as indicated below.

Customers must check the quality grade of each semiconductor product before using it in a particular

application.

"Standard": Computers, office equipment, communications equipment, test and measurement equipment, audio

and visual equipment, home electronic appliances, machine tools, personal electronic equipment

and industrial robots

"Special": Transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster

systems, anti-crime systems, safety equipment and medical equipment (not specifically designed

for life support)

"Specific": Aircraft, aerospace equipment, submersible repeaters, nuclear reactor control systems, life

support systems and medical equipment for life support, etc.

The quality grade of NEC semiconductor products is "Standard" unless otherwise expressly specified in NEC's

data sheets or data books, etc. If customers wish to use NEC semiconductor products in applications not

intended by NEC, they must contact an NEC sales representative in advance to determine NEC's willingness

to support a given application.

(Note)

(1) "NEC" as used in this statement means NEC Corporation, NEC Compound Semiconductor Devices, Ltd.

and also includes its majority-owned subsidiaries.

(2) "NEC semiconductor products" means any semiconductor product developed or manufactured by or for

NEC (as defined above).

•

Data Sheet PU10165EJ05V0DS 33

PC3220GR

NEC Compound Semiconductor Devices Hong Kong Limited

E-mail: ncsd-hk@elhk.nec.com.hk (sales, technical and general)

Hong Kong Head Office

Taipei Branch Office

Korea Branch Office

TEL: +852-3107-7303

TEL: +886-2-8712-0478

TEL: +82-2-558-2120

FAX: +852-3107-7309

FAX: +886-2-2545-3859

FAX: +82-2-558-5209

NEC Electronics (Europe) GmbH http://www.ee.nec.de/

TEL: +49-211-6503-0 FAX: +49-211-6503-1327

California Eastern Laboratories, Inc. http://www.cel.com/

TEL: +1-408-988-3500 FAX: +1-408-988-0279

0406

NEC Compound Semiconductor Devices, Ltd. http://www.ncsd.necel.com/

E-mail: salesinfo@ml.ncsd.necel.com (sales and general)

techinfo@ml.ncsd.necel.com (technical)

Sales Division TEL: +81-44-435-1588 FAX: +81-44-435-1579

For further information, please contact

PC3220GR