CY8C32_1105 CYPRESS [Cypress Semiconductor], CY8C32_1105 Datasheet - Page 54

CY8C32_1105

Manufacturer Part Number

CY8C32_1105

Description

Programmable System-on-Chip (PSoC) DC to 50 MHz operation

Manufacturer

CYPRESS [Cypress Semiconductor]

Datasheet

1.CY8C32_1105.pdf (120 pages)

Current page: 54 of 120
Download datasheet (4Mb)

Analog local buses (abus) are routing resources located within

the analog subsystem and are used to route signals between

different analog blocks. There are eight abus routes in CY8C32,

four in the left half (abusl [0:3]) and four in the right half (abusr

[0:3]) as shown in

globals and analog mux buses from being used for

interconnecting the analog blocks.

Multiplexers and switches exist on the various buses to direct

signals into and out of the analog blocks. A multiplexer can have

only one connection on at a time, whereas a switch can have

multiple connections on simultaneously. In

multiplexers are indicated by grayed ovals and switches are

indicated by transparent ovals.

8.2 Delta-sigma ADC

The CY8C32 device contains one delta-sigma ADC. This ADC

offers differential input, high resolution and excellent linearity,

making it a good ADC choice for measurement applications. The

converter can be configured to output 12-bit resolution at data

rates of up to 192 ksps. At a fixed clock rate, resolution can be

traded for faster data rates as shown in

Table 8-1. Delta-sigma ADC Performance

Figure 8-3. Delta-sigma ADC Sample Rates, Range = ±1.024 V

8.2.1 Functional Description

The ADC connects and configures three basic components,

input buffer, delta-sigma modulator, and decimator. The basic

block diagram is shown in

Document Number: 001-56955 Rev. *K

1,000,000

100,000

10,000

1,000

100

Bits

Continuous

M ulti-Sam ple

Maximum Sample Rate

Figure

Resolution, bits

8-2. Using the abus saves the analog

Figure

192 k

384 k

(sps)

8-4. The signal from the input

Table 8-1

Figure

SINAD (dB)

and

8-2,

Figure

8-3.

muxes is delivered to the delta-sigma modulator either directly or

through the input buffer. The delta-sigma modulator performs the

actual analog to digital conversion. The modulator over-samples

the input and generates a serial data stream output. This high

speed data stream is not useful for most applications without

some type of post processing, and so is passed to the decimator

through the Analog Interface block. The decimator converts the

high speed serial data stream into parallel ADC results. The

modulator/decimator frequency response is [(sin x)/x]

frequency response is shown in

Figure 8-4. Delta-sigma ADC Block Diagram

Figure 8-5. Delta-sigma ADC Frequency Response,

Normalized to Output, Sample Rate = 48 kHz

Resolution and sample rate are controlled by the Decimator.

Data is pipelined in the decimator; the output is a function of the

last four samples. When the input multiplexer is switched, the

output data is not valid until after the fourth sample after the

switch.

8.2.2 Operational Modes

The ADC can be configured by the user to operate in one of four

modes: Single Sample, Multi Sample, Continous, or Multi

Sample (Turbo). All four modes are started by either a write to

the start bit in a control register or an assertion of the Start of

Conversion (SoC) signal. When the conversion is complete, a

status bit is set and the output signal End of Conversion (EoC)

asserts high and remains high until the value is read by either the

DMA controller or the CPU.

(Analog Routing)

Input Mux

Negative

Positive

-100

-10

-20

-30

-40

-50

-60

-70

-80

-90

100

1,000

PSoC

Buffer

Input

Input frequency, Hz

Input Frequency, Hz

Modulator

Figure

3: CY8C32 Family

Sigma

10,000

Delta

8-5.

Decimator

Data Sheet

100,000

SOC

Page 54 of 120

; a typical

12 to 20 Bit

Result

EOC

1,000,000

CY8C32_1105 CYPRESS [Cypress Semiconductor], CY8C32_1105 Datasheet - Page 54

CY8C32_1105

Related parts for CY8C32_1105