ATA5428-PLSW80 Atmel, ATA5428-PLSW80 Datasheet - Page 22

RF Transceiver ASK/FSK Transceiver 434 and 868MHz

ATA5428-PLSW80

Manufacturer Part Number

ATA5428-PLSW80

Description

RF Transceiver ASK/FSK Transceiver 434 and 868MHz

Manufacturer

Atmel

Datasheet

1.ATAB5428-8-WB.pdf (100 pages)

Specifications of ATA5428-PLSW80

Wireless Frequency

226 KHz, 237 KHz

Interface Type

4-Wire SPI

Noise Figure

7 dB

Output Power

10 dBm

Operating Supply Voltage

2.4 V to 3.6 V

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

Package / Case

QFN-48

Maximum Data Rate

20 Kbps

Minimum Operating Temperature

- 40 C

Modulation

ASK, FSK

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Table 3-7.

3.13

Frequency (MHz) TX Current (mA) Output Power (dBm) R1 (k )

433.92

868.3

315

345

915

Output Power and TX Supply Current versus Supply Voltage and Temperature

ATA5423/ATA5425/ATA5428/ATA5429

Measured Output Power and Current Consumption with VS1 = VS2 = 3V, T

10.5

16.7

10.4

16.9

11.2

17.8

11.5

16.3

11.8

20.3

8.5

8.8

8.6

9.3

9.6

Table 3-8 on page 22

VS = VS1 = VS2 in the 433.92 MHz and 6.2 dBm case versus temperature and supply voltage

measured according to

opposed to the receiver sensitivity, the supply voltage has here the major impact on output

power variations because of the large signal behavior of a power amplifier. Thus, a two battery

system with voltage regulator or a 5V system shows much less variation than a 2.4V to 3.6V one

battery system because the supply voltage is then well within 3.0V and 3.6V.

The reason is that the amplitude at the output RF_OUT with optimum load resistance is

AVCC – 0.4V and the power is proportional to (AVCC – 0.4V)

changed. This means that the theoretical output power reduction if reducing the supply voltage

from 3.0V to 2.4V is 10 log ((3 V – 0.4 V)

ciple behavior in the measurement. This is not the same case for higher voltages, since here

increasing the supply voltage from 3V to 3.6V should theoretical increase the power by 1.8 dB;

but a gain of only 0.8 dB in the measurement shows that the amplitude does not increase with

the supply voltage because the load impedance is optimized for 3V and the output amplitude

stays more constant.

Table 3-8.

amb

VS =

= +25°C

= +85°C

–

40°C

Measured Output Power and Supply Current at 433.92 MHz, PWR_H = GND

10.5

10.7

10.2

-0.3

0.4

5.7

1.6

5.9

0.1

6.2

0.1

4.9

5.4

9.5

shows the measurement of the output power for a typical device with

Figure 3-10 on page 21

10.19 mA

10.62 mA

3.8 dBm

4.6 dBm

11.4 mA

3.9 dBm

2.4 V

VPWR_H

/(2.4 V – 0.4 V)

AVCC

GND

with components according to

Lopt

2500

2400

2300

1170

1100

920

350

900

320

890

300

471

245

465

230

10.19 mA

11.19 mA

12.02 mA

5.5 dBm

6.2 dBm

5.5 dBm

3.0 V

( )

) = 2.2 dB.

L1 (nH)

amb

if the load impedance is not

= 25°C

Table 3-8

C1 (pF) C3 (pF)

10.78 mA

11.79 mA

12.73 mA

shows that prin-

6.2 dBm

7.1 dBm

6.6 dBm

0.75

4841D–WIRE–10/07

3.6 V

1.5

2.2

3.9

1.2

1.8

3.9

1.5

2.7

1.0

1.5

0.7

1.5

Table

3-7. As

3.3

ATA5428-PLSW80 Atmel, ATA5428-PLSW80 Datasheet - Page 22

ATA5428-PLSW80

Specifications of ATA5428-PLSW80

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