CYRF7936-40LTXC Cypress Semiconductor Corp, CYRF7936-40LTXC Datasheet - Page 6

CYRF7936-40LTXC

Manufacturer Part Number

CYRF7936-40LTXC

Description

IC TXRX CYFI 2.4GHZ 40VQFN

Manufacturer

Cypress Semiconductor Corp

Datasheet

1.CYRF7936-40LTXC.pdf (22 pages)

Specifications of CYRF7936-40LTXC

Frequency

2.4GHz

Data Rate - Maximum

1Mbps

Modulation Or Protocol

DSSS, GFSK

Applications

Home/Building Automation, Industrial Control and Monitoring

Power - Output

4dBm

Sensitivity

-97dBm

Voltage - Supply

1.8 V ~ 3.6 V

Current - Receiving

21mA

Current - Transmitting

21mA

Data Interface

PCB, Surface Mount

Antenna Connector

PCB, Surface Mount

Operating Temperature

0°C ~ 70°C

Package / Case

40-VQFN Exposed Pad, 40-HVQFN, 40-SQFN, 40-DHVQFN

Receiving Current

21.2mA

Transmitting Current

26.2mA

Data Rate

1Mbps

Frequency Range

2.4GHz To 2.497GHz

Modulation Type

GFSK

Rf Ic Case Style

QFN

No. Of Pins

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Memory Size

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Functional Block Overview

2.4-GHz CyFi Radio Modem

The CyFi radio modem is a dual conversion low IF architecture

optimized for power, range, and robustness. The CyFi radio

modem employs channel-matched filters to achieve high

performance in the presence of interference. An integrated

power amplifier (PA) provides up to +4 dBm transmit power, with

an output power control range of 34 dB in seven steps. The

supply current of the device is reduced as the RF output power

is reduced.

Table 2. Internal PA Output Power Step Table

Frequency Synthesizer

Prior to transmission or reception, the frequency synthesizer

must settle. The settling time varies depending on the channel;

25 fast channels are provided with a maximum settling time of

100 µs.

The ‘fast channels’ (less than 100 µs settling time) are every third

channel, starting at 0 up to and including 72 (for example, 0, 3,

6, 9 …. 69, 72).

Baseband and Framer

The baseband and framer blocks provide the DSSS encoding

and decoding, SOP generation and reception, CRC16

generation and checking, and EOP detection and length field.

Packet Buffers and Radio Configuration Registers

Packet data and configuration registers are accessed through

the SPI interface. All configuration registers are directly

addressed through the address field in the SPI packet.

Configuration registers allow configuration of DSSS PN codes,

data rate, operating mode, interrupt masks, interrupt status, and

so on.

SPI Interface

The

communication between an application MCU and one or more

slave devices (including the CYRF7936). The SPI interface

supports single-byte and multi-byte serial transfers using either

4-pin or 3-pin interfacing. The SPI communications interface

consists of slave select (SS#), serial clock (SCK), MOSI, MISO,

or SDAT.

Document Number: 001-48013 Rev *E

CYRF7936

PA Setting

has

Typical Output Power (dBm)

SPI

interface

–13

–18

–24

–30

–35

–5

supporting

SPI communication is described as follows:

■

The device receives SCK from an application MCU on the SCK

pin. Data from the application MCU is shifted in on the MOSI pin.

Data to the application MCU is shifted out on the MISO pin. The

active LOW SS# pin must be asserted to initiate an SPI transfer.

The application MCU can initiate SPI data transfers using a

multibyte transaction. The first byte is the Command/Address

byte and the following bytes are the data bytes as shown in

Table 3

The SPI communications interface has a burst mechanism,

where the first byte can be followed by as many data bytes as

required. A burst transaction is terminated by deasserting the

slave select (SS# = 1).

The SPI communications interface single read and burst read

sequences are shown in

respectively.

The SPI communications interface single write and burst write

sequences are shown in

respectively.

This interface may be optionally operated in a 3-pin mode with

the MISO and MOSI functions combined in a single bidirectional

data pin (SDAT). When using the 3-pin mode, firmware must

ensure that the MOSI pin on the MCU is in a high-impedance

state except when MOSI is actively transmitting data.

The device registers may be written to or read from one byte at

a time, or several sequential register locations may be written or

read in a single SPI transaction using incrementing burst mode.

In addition to single byte configuration registers, the device

includes register files. Register files are FIFOs written to and

read from using nonincrementing burst SPI transactions.

The IRQ pin function may be optionally multiplexed to the MOSI

pin. When this option is enabled, the IRQ function is not available

while the SS# pin is LOW. When using this configuration,

firmware must ensure that the MOSI pin on the MCU is in a high

impedance state whenever the SS# pin is HIGH.

The SPI interface is not dependent on the internal 12 MHz clock.

Registers may therefore be read from or written to when the

device is in sleep mode, and the 12 MHz oscillator disabled.

The SPI interface and the IRQ and RST pins have a separate

voltage reference pin (V

directly to MCUs operating at voltages below the CYRF7936 IC

supply voltage.

Command direction (bit 7) = ‘1’ enables SPI write transaction.

When it equals a ‘0’, it enables SPI read transactions.

Command increment (bit 6) = ‘1’ enables SPI auto address

increment. When set, the address field automatically

increments at the end of each data byte in a burst access.

Otherwise the same address is accessed.

Six bits of address

Eight bits of data

through

Figure 6

on page 7.

). This enables the device to interface

Figure 4

Figure 6

and

Figure 5

Figure 7

CYRF7936

Page 6 of 22

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