Z85C3010PSG Zilog, Z85C3010PSG Datasheet - Page 292

Z85C3010PSG

Manufacturer Part Number

Z85C3010PSG

Description

IC 10MHZ Z8500 CMOS SCC 40-DIP

Manufacturer

Zilog

Series

SCCr

Datasheets

1.Z85C3008PSG.pdf (71 pages)

2.Z85C3008PSG.pdf (4 pages)

3.Z85C3008PSG.pdf (317 pages)

Specifications of Z85C3010PSG

Processor Type

Z80

Features

Error Detection and Multiprotocol Support

Speed

10MHz

Voltage

Mounting Type

Through Hole

Package / Case

40-DIP (0.620", 15.75mm)

Cpu Speed

8MHz

Digital Ic Case Style

DIP

No. Of Pins

Supply Voltage Range

Operating Temperature Range

0Â°C To +70Â°C

Svhc

No SVHC (18-Jun-2010)

Base Number

Rohs Compliant

Yes

Clock Frequency

10MHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

269-3934
Z85C3010PSG

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UM010901-0601

Load Capacitors

In the selection of load caps it is understood that parasitics

are always included.

Upper Limits. If the load caps are too large, the oscillator

will not start because the loop gain is too low at the

operating frequency. This is due to the impedance of the

load capacitors. Larger load caps produce a longer

startup.

Lower Limits. If the load caps are too small, either the

oscillator will not start (due to inadequate phase shift

around the loop), or it will run at a 3rd, 5th, or 7th overtone

frequency (due to inadequate suppression of higher

overtones).

Capacitor Type and Tolerance. Ceramic caps of 10%

tolerance should be adequate for most applications.

Ceramic vs. Quartz. Manufacturers of ceramic resonators

generally specify larger load cap values than quartz crystals.

Quartz C is typically 15 to 30 pF and ceramic typically 100 pF.

Summary. For reliable and fast startup, capacitors should

be as small as possible without resulting in overtone

operation. The selection of these capacitors is critical and

all of the factors covered in this note should be considered.

Feedback Element

The following text describes the specific parameters of a

typical crystal:

Drive Level. There is no problem at frequencies greater

than 1 MHz and V

crystals are designed for relatively high drive levels (5-10

mw max).

A typical calculation for the approximate power dissipated

in a crystal is:

Where. R = crystal resistance of 40 ohms, C = C1 + Co =

20 pF. The calculation gives a power dissipation of 2 mW

at 16 MHz.

Series Resistance. Lower series resistance gives better

performance but costs more. Higher R results in more

power dissipation and longer startup, but can be

compensated by reduced C1 and C2. This value ranges

from 200 ohms at 1 MHz down to 15 ohms at 20 MHz.

Frequency. The frequency of oscillation in parallel

resonant circuits is mostly determined by the crystal

(99.5%). The external components have a negligible effect

(0.5%) on frequency. The external components (C1,C2)

and layout are chosen primarily for good startup and

reliability reasons.

P = 2R ( x f x C x V

= 5V since high frequency AT cut

)

Frequency Tolerance (initial temperature and aging).

Initial tolerance is typically .01%. Temperature tolerance

is typically

degrees C). Aging tolerance is also given, typically

Holder. Typical holder part numbers are HC6, 18,

25, 33, 44.

Shunt Capacitance. (Cs) typically <7 pf.

Mode. Typically the mode (fundamental, 3rd or 5th

overtone) is specified as well as the loading configuration

(series vs. parallel).

The ceramic resonator equivalent circuit is the same as

shown in Figure 4. The values differ from those specified

in the theory section. Note that the ratio of L/C is much

lower than with quartz crystals. This gives a lower Q which

allows a faster startup and looser frequency tolerance

(typically 0.9% over time and temperature) than quartz.

Layout

The following text explains trace layout as it affects the

various stray capacitance parameters (Figure 9).

Traces and Placement. Traces connecting crystal, caps,

and the IC oscillator pins should be as short and wide as

possible (this helps reduce parasitic inductance and

resistance). Therefore, the components (caps and crystal)

should be placed as close to the oscillator pins of the IC as

possible.

Grounding/Guarding. The traces from the oscillator pins

of the IC should be guarded from all other traces (clock,

usually accomplished by keeping other traces away from

the oscillator circuit and by placing a ground ring around

the traces/components (Figure 9).

Measurement and Observation

Connection of a scope to either of the circuit nodes is likely

to affect operation because the scope adds 3-30 pF of

capacitance and 1M-10M ohms of resistance to the circuit.

Indications of an Unreliable Design

There are two major indicators which are used in working

designs to determine their reliability over full lot and

temperature variations. They are:

Start Up Time. If start up time is excessive, or varies

widely from unit to unit, there is probably a gain problem.

C1/C2 needs to be reduced; the amplifier gain is not

adequate at frequency, or crystal Rs is too large.

.005%.

, address/data lines) to reduce crosstalk. This is

.005% over the temp range (-30 to +100

On-Chip Oscillator Design

Application Note

6-157

Z85C3010PSG Zilog, Z85C3010PSG Datasheet - Page 292

Z85C3010PSG

Specifications of Z85C3010PSG

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