A search for where or when the word baseline emerged, while interesting, is likely to shed little light on its potential meaning and role in modern natural resource management. Hirsch (1980:86) looked for a definition but, finding none, deduced that it meant "a description of conditions existing at a point in time against which subsequent changes can be detected through monitoring." If this definition is accepted, it delimits to a large extent the role of baseline studies in environmental impact evaluation. Under this definition, the baseline study is not a predictive tool; its principal use is for post hoc detection of change. As such, a baseline study would be of limited utility in meeting the requirements of an environmental impact statement. These requirements tend to be for predictive work. Nevertheless, the present needs to be defined.

Hirsch acknowledged that the rationale and expectations for baseline studies are not clear or widely accepted. He observed that in practice, "baseline" is quite loosely used to cover a range of information required, at least for purposes of environmental impact assessment. It is often found intermixed with "inventory" and "monitoring." Hirsch (1980:85) described an ocean baseline sampling program that was designed to detect long-term oceanic changes. The need was seen for "...both one time and continuing surveys." These implied surveys that were needed to help "...establish a baseline for analysis." The wording suggested that "baseline" is a concept of a standard over time unlike most uses of the word which seem to mean a measure of many factors at one time. The "prior use" concept is a principle of biological taxonomy. Herein we may transgress the principle, but the greater fear is that a full understanding and development of a modern, computer-enhanced and useful concept of baseline will be delayed. Baseline studies have been called "trend assessment surveys." We use "baseline", assuming the first users were not trying to be scientifically precise or rigorous in their definition, that there was no flaw in the definition, and that it has not already been replaced by another word or by someone else's definition. (Figure 1). This section attempts to synthesize concepts of baseline studies. It tries to develop a solid platform of understanding and collective wisdom from which baseline studies might be begun. It explains the point of view and basis for planned work. Hopefully that point of view will be supported but, if not, this section presents a basis for discussion and constructive adaptations for the future. Within Guidance as used on the area may some day emerge an analysis system that serves the interests of people for each land area and one that can demonstrate usefulness as a "...base for land-management and regional planning decisions involving such uses as forestry, recreation, wildlife, selection of natural areas..., transportation..." (Lacate 1973:14), water, utility and other development.

Fig. 1. There are several general concepts of base depicted as (A1) a singular or summary observation about a system or a factor. It is used to express change over time. An alternative, (A2), is a set of observations about factors or systems with emphasis on change including variance. The condition (A3) suggests a line of factors, all to be studied over time. The line seen in (A4) may be the concept often meant, namely studies done before some time t, where t is the line drawn in time with studies done before that being the base to which other later observations may be compared. Another use (B) is as a particular distribution or pattern to which a point or set may be compared.

Over many years the value of wilderness to science has been listed. This is an assertion about potentials. There are few such studies, studies which are significantly different than studies that can be conducted on non-wilderness or non-"natural area" land and water. Within Guidance is support for the value of wilderness as "the base datum of normalcy" (Leopold 1949). The "datum" has always implied that there would be some use of it and that it would be for determining some (1) condition, (2) difference, (3) trend, or (4) future state.

There are conditions other than wilderness, natural areas, and critical areas in which baseline concerns are relevant. These include:

1. Non-specific global change (e.g., to learn of all types of effects of global warming)
2. Development (e.g., to learn of changes after a major land use project is completed)
3. Use (e.g., to measure effects of parkland use and to decide on limitations to further change)
4. Succession (e.g., to learn of natural change in communities)
5. Comparisons (e.g., temporally specific conditions for comparison between or among areas, times, and treatments)
6. Basic (e.g., descriptions of the duration of associations of animals with plant-based communities).

A long-term ecological monitoring program provides the framework in which to obtain the required information. Monitoring programs can, with analyses and use: 1) provide measures of an ecosystems's stability; 2) test the reliability of predictive models; 3) give warning of trends judged to be undesirable; 4) provide information for developing management plans; and 5) provide one means for success of management programs to be judged.

One of the tasks of the Scientific Committee on Problems of the Environment, International Council of Scientific Unions (Scope 1971:15) was "... to investigate the usefulness of studying past changes in selected parameters in order to establish baseline values and to investigate the possibilities of establishing environmental archives..."

Scope (1971:60) observed:

quot; One of the main objectives of the reference stations is to establish trends. In addition to this it is important to extend the "baseline" backwards in time by a process of "historical monitoring." The chemical stratigraphy of marine and lake sediments, peat bogs, glacier and ice cores and similar time-layered materials should be analyzed. Coral reefs, tree rings, herbarium and museum specimens of biota collected in former times have all been shown to be highly informative in this respect. As an extension of this activity, it would be essential to develop an efficient storage of collected samples as an environmental archive. Soils, water, biota and air filter samples preserved by deep freezing could be of great value in the future."

Scope (1971:6) recommended that:

"...an international, integrated network of reference stations (low exposure or baseline and medium exposure or regional areas, transects or sites) based on national activities be established for the collection of data pertinent to global environmental monitoring."

Also (Scope 1971:10) recommended:

"The design of a system for preserving samples from air, water, soils, and biota in order to make future re-examination of past environmental conditions possible (environmental archives)."

"Archives are becoming increasingly expensive to maintain and, as data collection continues unabated, increasingly difficult to manage. Still, as the rate of social and environmental change continues to increase, archives and collections are among the few links to the past available to researchers" (George et al. 1986:12).

Baseline studies have become an accepted element of many environmental protection programs, partially in response to NEPA (Hirsch 1980:84). Hirsch observed that the Bureau of Land Management required a 2-year environmental baseline and monitoring program as part of oil shale development, and listed many other baseline studies, mostly needed prior to major developments. "Heavy reliance is being placed upon baseline studies to help decision-makers meet the intent of NEPA and other environmental regulations" (Hirsch 1980:84). He also said that baseline studies are "...necessary to provide understandings which can help minimize environmental impact of various developments and reconcile the inherent conflict between environmental protection and economic development..." (Hirsch 1980:84).

Hirsch observed that for ocean waste disposal sites, baseline studies have the purpose of determining

"...the physical, chemical, geological, and biological structure of a proposed or existing disposal site at the time of the survey. A baseline or trend assessment survey is to be regarded as a comprehensive synoptic and representative picture of existing conditions; each such survey is to be planned as part of a continual monitoring program through which changes in conditions at a disposal site can be documented and assessed."

Bratton (1989:103) said that confusion about management of scientific projects in wilderness has discouraged many environmental monitoring projects from utilizing wilderness. She said (1989:108)

"at the very least, there is a national need for basic environmental monitoring in wilderness, to establish baseline information banks for attacking site integrity questions. This effort needs to encourage basic ecological research, including all types of biological surveys and descriptive studies."

Wolfe (1983) said that mined land revegetation success standards may best be selected according to post-mine land use and site specific requirements. Formulating those requirements may require a standard and she suggested an historical data base as appropriate. "Historical records allow various means of data manipulation for comparison purposes and is one approach for establishing a flexible, relevant revegetation success standard."

Tiarks et al. (1991) described a network of long-range experiments proposed for forests of the U.S. to evaluate the effects of soil compaction and organic matter removal on soil productivity.

Green and Franklin (1989:115) said

"most of the research being done tends to be short-term and lack an holistic emphasis. Although every study contributes to our overall understanding of ecological processes, baseline information on a wider range of natural processes is needed. Such studies need to be carefully designed to identify trends and improve our understanding of natural processes. A repeated series of measurements or permanent sample plots with certainty of funding is badly needed to identify trends."

Baseline studies (Hirsch 1980:85) establish existing background levels and conditions so that future changes can be ascertained. They may warn of unsuspected effects.

Trends

The objective of most observations among the 6 conditions above is said to be "to discover trends." Among the objectives of the International Council of Scientific Union's Scientific Committee on Problems of the Environment (Scope 1971) was "projecting current environmental trends into the future on the basis of alternative hypotheses of future human activity, population, use of natural resources and energy requirements..." Herein we discuss the meaning(s) of this apparently straight-forward intent.

An ecosystem, as it presently exists, can be observed, but it is difficult to do so. It is very much a function of and related to nearby things. Rarely can an entire system be observed. Even then, most sensory experiences are limited; the pure one is reached only through careful training. The observed present ecosystem only achieves meaning when its past is included in the observation. It achieves relevance when the future conditions are predicted. An ecological observation, therefore, perhaps more so than any other type of observation, is temporally complex. It is past, present, and future. This section of R* Guidance addresses that complexity; it is a probe of the concept of "baseline."

Presence

There are interval phenomena in the ecosystem: one fern, one bird. Each is named; all names are taxa. One plant of a species is seen. The observation is:

K_s,i,t

for I saw K (a count)specimens of the sth species, in the i th region, at time t (e.g., 24 November 1994). A simple observation can become difficult to analyze since the observation may have been of a subspecies or variety, thus slightly misidentified.

We can see several types of errors arising in formulating a description of things present:

• Class 1 - Calling something present when it is not (related to statistical Type 1 error) a - slight error (taxonomically similar) symbolized as E less than 1.0 and grester than 0. Even the best observers make mistakes (of various types) so that the observation was not of i=species number 10 but of i = species number 36. b - total error (mis-named taxon) symbolized as E = 1.0.
• Class 2 - Calling something present with a high (but not 1.0) probability (based on historical records or observations, known associations, or trends) when it is no longer present.
• Class 3 - Falsifying an observation of presence.
• Class 4 - Missing an observation of something; by omission, implying it is absent when it is present related to statistical power or (1 - beta) (cf Peterman 1990:2024). (The probability of rejecting the hypothesis of non-presence when there is a species present.)
• Class 5 - Saying something is absent. (A logical error, since absence is very difficult to prove.)

Because there are errors, possible and very likely, then we can, in our final computations and thought processes, include as a standard presence the value of E (of whatever type) that is probably time-specific, thus

K _s,i,t (1.0 + E) E is a proportion (zero to 1.0) and may be plus or minus. Hopefully it will be close to zero. E, even though called an "error term", should not connote evil, inefficiency, slovenliness or any such ideas. It is used to recognize the difficulty of a pure sensation or perfect observation and is a means to express and therefore estimate and compute the difference between the observed and actual conditions of the system.

Richness

Presence studies often result in "checklists", the core of so-called richness studies. Taxa can be counted. Richness is the total number of taxa present in some specified group. A "group" could be "riparian (stream side) birds" or "grassland mammals." There are several types of richness used by various students of areas. Where R is richness, then

(1)

meaning simply the sum of all of the "ones" observed for all n species at time t. Richness is of interest but discovering trends is said to be a major basis of baseline work. One elementary consideration is to estimate a rate, r₁, by

r₁ = (R_t+1 - R_t)/R_t (2)

For example, where there were once 50 species and there are now at time (t+1) only 48, then

Fig.2. Three descriptions of how conditions of a baseline value, Q, may change and the difficulty that may be experienced in determining whtehr change is significant. If we could somehow learn that the ecological system being studied fluctuated regularly, then we would probably not be worried about the drastic-appearing rate of change from a to b in A. The system would soon return, naturally, to the level of a. Of course knowing whether a system is cyclic or if future levels are predictable is also the problem and one of the reasons why baseline, monitoring, or inventory projects are needed. In B, determining the time at which Q levels of, b, may be very difficult. In C, the difference in fluctuations is difficult to determine.

r₁ = (48-50)/50 = - 0.04

and a 4 percent loss is reported. This is equivalent an expression of a condition in relation to its "former self", the baseline, being

r₂ = (1.0 - |r₁| ) x 100 (3)

where r₁ is the rate of change (as absolute value) as above. When r₁ is 0, then there is no change and r₂ = 100%.

The problem with a simple rate computation such as r₁ or r₂ is that shown in Fig. 2.

Sokol and Rolf (1969) presented a procedure for comparing the rates of two linear regressions. The test is for whether the beta values are significantly different. If a baseline is of type a to b in 2B, then is the rate of b to c in 2B significantly different than for a to b? It is easy to imagine situations in which, on average, there has been no change. In complex systems, linear time-series are rare. For example, the biomass succession curve may be of a form shown in Fig. 2C. Toxicants, the greenhouse effect, or other phenomena may cause a change in the shape of the curve, the dynamics. Computing complex curves is difficult; comparing them even more so; deciding on whether the difference is ecologically or economically significant or in terms of human health "significant" is almost impossible.

The comparative nature of these relations leads to the observation that some basis for comparison is needed. "Has there been change?" is a reasonable question.

"As compared to what?" is a reasonable sequel prior to an answer. Answer: as compared to R_t , a previously observed condition. That condition is the basis for comparison, the base. (Whether "-line" must be added to "base" can be discussed. Perhaps prior usage may make it appropriate.)

Stability: Relative Constancy

"Ecological stability" seems intuitively to be desirable. Many people express stability as an objective in various publications. We suspect that it is desirable but we are not sure if the ecological condition today is the level at which we should stabilize things. Herein we temporarily surrender in the face of the enormity of defining the desired level and accept the premise that people desire to retain indefinitely (at least for 50 years) at least the ecosystem of today. This condition might be called a baseline. Over time, this condition should remain approximately constant if the system is stable.

How will I know when we have achieved such stability? It is always difficult to know anything. Knowing about ecosystems is unusually difficult.

Stability problem No. 1, a topic unto itself, is one of deciding the system performance measure. What will we measure and plot; what parameter measurement and units will we use for our computations? Not ignoring but merely dodging the issue for now, we assume some parameter can be selected or decided upon. For example only, let us say that birds seen along transects each spring is the agreed-upon integrative measure. Implicitly: if bird numbers are stable, then the ecosystem is stable.

Stability problem No. 2, the major emphasis in this section, is its computation. If the observed birds, S_xi, have a value of 60 in the base year and a computed rate of change of zero, then is the system rate of change zero? Perhaps. Some will ask about how variable are the observations over the years and whether the similarity (or differences) could be due to chance or random events, thereby the bird count would not be reflecting the ecosystem at all.

It is apparent that there are 2 major dimensions of the question, 1 structural the other functional. Fedorov (1975) made this point. He said stability is a measure of the temporal inconstancy of a function. It expresses the variation around a mean over time. The variation can be measured as:

• The mean of the deviation in the range
• The variance or standard deviation in the observations
• The ratio of the geometric mean to the arithmetic mean value of the observations.

These values express annual changes (from whatever causes or forces). These expressions of variation are seen as evidence of functional aspects of the ecosystem.

We may use 1 measure, such as for birds, vi, and average them for a period then compute variance during that period. "How different is the system each year from the mean?" seems like a reasonable question. "How different is it from the first year, the base year?" also seems reasonable. The ratio of the standard deviation to the mean, the coefficient of variation, is well known in statistics. By comparing the variance to the mean, the results is Federov's G which is

G = 1-(V/M) x 100 (4)

Note that when M=V the conditions are Poissonal, often said to be evidence of a random state, and thus G = 1 and the condition is equivalent to a non-system each year or a completely new system apparently arising at random. (This analysis of G, while useful, falls short when we consider thresholds (excessive deviation) or the combined action of factors (e.g., pH on aluminum toxicity). We may then make G conditional upon no ecosystem element, xi, passing a "permissible measure.") Similarly there may be invariants in the system (e.g., cyclic lynx or P/R ratio). Thus we may make V conditional upon vi being constant or greater than some level.

Many people prefer factor-by-factor analyses of large systems. Even they realize that there are uncertainties in each factor and most of them are changing over time, some increasing, some decreasing but all at different, varying rates. Decision makers usually only do one thing (e.g., build a pond) but every act potentially influences at least 500 nameable, measurable ecological factors in regional ecosystems. A simple table for 50 years suggests 50x500 entries, an equivalent table for uncertainties, ranges, and probabilities. The minimum question seems always to be: Is is all right to change the environment? Then: Compared to what? Net effect. Then: Compared to what? and eventually the answer returns to: baseline. This answer to what is a good baseline for most practical ecologists is wilderness (with no value connotation, no notion of "good" or "best", only a standard), or today's measured condition. Foresters use "the normal forest." I believe there should be devised a computerized concept of the standard ecosystem. Its singular role (beside education) would be as a basis for making comparisons of other ecosystems before and after actual or proposed change.

Significance of Change

Whether any change over time is "significant" or whether there is a "significant difference" between two numbers like 50 and 48 is a matter of economics, not ecology, for it is grounded in the worth, value, or relative importance of one unit of change and influences how scarce resources will be allocated. The loss of a prize race horse would seem to be a good example. It may be worth millions of dollars and have great personal value but that total value will surely shift if the horse is in a stable of 100 horses or in one containing merely 3 horses. The points: (1) each species has value and that value is likely to differ between species, (2) the loss of one species may not be equivalent to the loss of another, and (3) the value is related to the context; the value of some species is probably related to knowledge of the presence of other species. (The more there are, the less important is any one species on the grounds of ecological adaptability, niche shifts, and our limited ability to perceive changes.) Hirsch (1980:91-92) talked about 2 kinds of "so what?" questions. The first is about changes produced and whether irreversible damage has occurred. In one sense, this is the question of real impact, but it is unresolvable because "damage" is not definable without a concept of value. This problem leads to the second "so what?" which is a question of tradeoffs between the benefits of a proposed project or action and the costs, losses, or perceived damage. The latter, Hirsch said, is outside the arena of environmental impact assessment but this seems very controversial in light of the need to compare alternatives. He suggested that assessments should provide the information that make the value choices more clear.

Taxonomy

The list of life forms present, plants or animals, may increase by 10 percent in one year. This may be due to migration, drastic land use change, or the presence of a taxonomic specialist! I am not raising the debate of "lumpers and splitters" but only recognizing the role of the taxonomist in the issue of deciding presence or absence of a taxon. There are groups of plants, for example, that are difficult to identify for various reasons (e.g., Carex, Vitis, Salix). That is why they are so frequently listed as genus followed by spp. A specialist arriving in an area at the proper time (e.g., flowering) can name species and subspecies, adding many taxa to one listed before as "Genusspp."

Baseline work teeters on an edge, perhaps a point, called taxonomy. A world expert on a group such as the microlepidoptera might prepare a long list of species for a forest. The insects may never again receive the same scrutiny. How will such lists be handled? Is past knowledge to be ignored? Must all species and subspecies lists be collapsed to Genus? The insects, as other life forms, suggest the need for taxonomists able to discriminate species or subspecies differences among larvae, pupae, and adults... for each species! Plant seeds suggest a similar taxonomic problem in the plant realm. A seed is seen and collected. It cannot be identified. Is it to be placed into some "other" class? Will it be withheld to await naming? What are the consequences (to anyone, to a baseline list, to a species count, to an index expressive of biodiversity) of ignoring things not nameable with confidence or naming everything?! What are the consequences of changing names: (1) due to expansion or contraction based on accepted taxonomic standards and keys; (2) due to expansions from increasingly precise work; (3) due to regrouping life stages e.g., realizing seed No. 113 is equivalent to herbarium plant No. 46 and thus the list of plants decreased by 1; or (4) due to reductions from misidentifications.

I see no easy or likely-to-be-acceptable way out of this extremely complex area. It needs resolution because laws now require attention to biodiversity and for many people that means giving attention to lists of species, and to most people it implies that the list should not be shortened (i.e., species "extirpated"). That the list can be shortened by a taxonomist (not by biological or other extinction phenomena) needs to be recognized. Overly long lists probably exist (due to misidentification and unjustified separations which are now seen as being the same through DNA analyses, etc.) and these need to be shortened. Use of DNA analyses will increase the length of others. Four Premises

It seems reasonable that all analyses of the taxa of an area should report counts made within each taxon. These should start at "Kingdom" and become more precise, even to the level of "variety"(for there are areas where domesticated plants are very much a part of the present ecosystem (as in historic areas of the National Park Service).) Such listing allows cumulative or dis-aggregated analyses to be performed for various purposes.

A second premise for baseline work is one of pragmatism. We must use the names of the taxa available to us. We must at least attempt to count and understand the meaning of the presence of each nameable entity. When we see or suspect important roles of observed but un-named forms, then we must get taxonomic work done.

A third premise is general but of utmost importance. We have not collected and named the creatures and plants of hardly any area. We cannot study the interactions (said by some to be "ecology") of plants and animals if we cannot even name those that occur. We, at least, must allow and encourage biological identification (systematics) to regain a respectable role in university education and agency work.

You see it; it is present! Perhaps. Perhaps it is misidentified, perhaps a flawed observation. You do not see it; it is absent! Of the following statement we can be certain: that statements about the certainty of being absent cannot be proven. Many biological phenomena are transitory. There are plants that only appear briefly in the spring; birds migrate; some species are cyclic; some animals hibernate; some have very long periods of development and behavioral stages (See Time Section). As always, rarity decreases the probability of observation. Even developmental stage (e.g., a fern embryo) influences observability and detection of presence. Many people will say "species X should be here. The conditions are right; all of the associates are present. I do not see it today." Timing, time spent, conditions, and the observer's abilities are all part of the observation of "presence." While extreme uncertainty of taxonomy may engulf the observer, an equal difficulty enshrouds those that are knowledgeable about ecosystem changes over short periods. For example, birds shift migration patterns. Hundreds are present one year, none seen the next (even though the total abundance is the same). Salamanders migrate to the upland woods and return to breeding areas 8 years later. The time is "t" but to the ecologist the time is always in error. It must be many years, at least a decade to be practical. Quibbling about sample sizes of less than 30 on statistical grounds and ignoring temporal change is folly.

The result of these premises about "presence" is that the phenomenon requires use of a presence probability table (Table 1). Creating the table has all of the requirements for appropriate observation techniques and sampling intensity. Some species, e.g., species 5 was not observed (as seen in Table 1); it has a probability, however small, of being present.

Table 1. Example of a presence probability table. The probability of presence (indicated by X) of five hypothetical species is based on four sampling periods. Species Date Probability (K) 1 2 3 4 1 X X X 0.75 2 X X 0.50 3 X X 0.50 4 X 0.25 5 greater than 0.

"Expected richness", an observation for some year t, is the sum of the products of the probability and actual occurrence, and is: n

R2t = S SitK i=1

Richness (also viewed by some as "biodiversity") has been described as

R3t = R2t -1 (5)

One basis for this formulation is that an area with only one species has no richness (i.e., 1-1=0).

When the number of species is very large, the subtraction rarely has any effect on other computations on their results.

When all items are counted giving a total of N (e.g., plants), then richness can be formulated as

R4t = R3t / log10 (N+1) (6)

providing a statistically unbiased estimator. For example, when there are 20 species and 2000 creatures, then

R4t = (20-1)/log (2000 + 1)

R4t = 19/3.3 = 5.76

This can be compared to a situation of more species, say 30, but with fewer specimens in each, say 1000, as

R4t = 29/log (1000 + 1)

R4t = 9.67

The larger numbers (greater richness?) exist when there are few creatures per taxon (i.e., evenly distributed). When there are only 20 creatures and 20 taxa, then R4t = 14.37. When there are 300 creatures and 300 taxa, then R4t = 120.6. It is doubtful if maximizing richness or this index is what is intended by well-meaning advocates of "biodiversity." It represents one basis for making comparisons but keeping the two measures (species and abundance) separate may be a reasonable strategy for the near future.

Abundance

Counts of things represent abundance. There are 3 plants of species No. 1, 10 of species No. 2. Abundance is typically species- or taxon-specific. In some studies of biomass it is an expression of weight.

In baseline studies, change in abundance is of equal and usually more interest than change in richness. "Species 1 increased to 10 and species 2 decreased to 3 plants over 10 years" would be a representative finding. "I was correct in my listing within 3 or 4 plants" would not be an unexpected statement of a field observer. There are many reasons for such apparent imprecision as field workers well known. With small numbers observed, the results can, if taken literally, result in an observation of 3 plants meaning "from minus 1 to 7 plants." Except for temperature, I know of few natural minus-number conditions in ecology. This usually means that the frequency of observations is not normally distributed (not bell-shaped).

Baseline work may require comparisons of abundance observations each with an error term, sometimes expressed as a percentage of the observation. ("I am no more than 1 or 2 percent off!") Table 2 shows some results of this phenomenon and the difficulty of comparisons. Element 4 may not have changed at all. Ratliff and Mori (1993) provided a "squared Euclidian distance" procedure for analyzing these changes.

Because density estimates are so poor, and error terms so large, one reasonable thing to do with them is to collapse them into "probable richness", larger numbers merely suggesting larger probability of detection in future studies. No matter how sophisticated the analyses (e.g., Poisson analyses of the probability of rare events or binomial analyses of presence-absence sequences), there is little that can be done to improve the environment for decisions about rareness.

Diversity

Patil and Tallie (1982) have analyzed diversity indexes, found most of them flawed or closely correlated, and found that many, at best, expressed average rarity. Between-period comparisons cannot be made properly with most diversity indexes. They are notoriously equifinal; very different numbers produce the same Simpson or Shannon diveristy index. If there is a "point" to be made, the probability of any ability to compare ecosystems using baseline observations is very low. It will be contended by some people that the upper limit of goodness is the upper estimate on the error term (the largest percentage as in Table 1.) See the section of Guidance on "Variety."

Analyses of Changes in Elements

Changes determined by the post hoc analyses that are assumed for baseline studies are likely to occur in at least the following areas (partially based on Ohmann and Ream 1971):

Table 2. A set of hypothetical observations made with baseline at time t. Trying to find an appropriate means to discuss ecosystem change (here a simple one of 5 elements) is difficult. Change in each element is a standard practice.

Time t Time t+1 Ecosystem Element Observed Value % Range Observed Value % Range 1 3 5 2.85 - 3.15 4 10 3.60 - 4.4 2 5 10 4.50 - 5.50 8 5 7.60- 8.4 3 20 2 19.60 - 20.40 17 3 16.49 - 17.51 4 30 5 28.50 - 31.50 36 10 31.50 - 38.5 5 6 20 4.80 - 7.20 12 30 8.40 - 15.60

1. General
   1. Total area
   2. Boundary length
   3. Remoteness
   4. Lakes
   5. Streams
   6. Hydrography
   7. Surficial geology
   8. Topography
      • Slope
      • Aspect
      • Slope position
      • Elevation
      • Roughness indices
   9. Existing trails
   10. Scenic vistas
   11. Scenic quality
   12. Unique landmarks
   13. Growing seasons
   14. Diversity indices
2. Vegetation
   1. Checklist
   2. Richness (numerical)
   3. Density
   4. Distribution
   5. Diameters
   6. Basal area
   7. Growth rate
   8. Leaf area index
   9. Presence of introduced plants
   10. Height zones (layers)
   11. Zone percent(s)
   12. Canopy coverage
   13. Understory stem count
   14. Ground coverage
   15. Plant litter on ground
   16. Soil wood
   17. Down logs
   18. Conifers present
   19. Conifer-bloadleaf ratio
   20. Height
   21. Age distribution
   22. Amount of forage available
   23. Plant hedging caused by animals
   24. Community area
   25. Site index
   26. Fuel loading
   27. Snags
   28. Standing dead trees
   29. Presence of fire
   30. Presence of domestic animal grazing
   31. Habitat type
   32. Select species analyses
   33. Habitat requirements
   34. Probable distribution
3. Fauna
   1. Checklist (taxa present)
   2. Richness (numerical)
   3. Seasonal occurrence
   4. Density
   5. Insect presence
   6. Insect defoliation estimate
   7. Track counts
   8. Behavioral transects (drumming, etc.)
   9. Needs present
      • Feeding
      • Breeding
      • Resting
      • Spacing
   10. Fish collections
   11. Water
   12. Precipitation (all types)
   13. Evapotranspiration
   14. Minimum flow
   15. Maximum flow
   16. Flood stage
   17. Color-General description
   18. Nitrogen compounds
   19. Phosphorus
   20. Electric conductance
   21. Toxic substances
   22. Total coliforms
   23. BOD
   24. COD
   25. DO
   26. pH
   27. Temperature
   28. Ambient temperature
   29. Sediment
   30. Turbidity
   31. Dissolved solids
   32. Odor intensity index
   33. Springs
   34. Seeps
   35. Stream channel depth, shape, and location
   36. Snowbanks occurrence
4. Soil
   1. Erosion
   2. Depth to bedrock
   3. Rock outcrops
   4. Gully formation or closure
   5. Changes in roads
   6. Changes in buildings
   7. Texture
   8. Nitrogen
   9. Phosphorus
   10. Potassium
   11. Organic matter
   12. Pollutants
   13. Bulk density
   14. Nearness to water
5. Use
   1. Access
   2. Nearness to roads and towns
   3. Presence of recreational users
   4. Presence of non-recreational use
   5. On site management present
   6. Social interactions
   7. Presence of management regulation
   8. Presence of tracks (ORV)
   9. Irreversible evidence of people
   10. Renewable resource modification
   11. Noise

   The very general questions being raised (perhaps not adequately addressed) are "where have we been in our descriptions and analyses; where should we go?" Interpretation is needed. Field experience needs to be applied somehow.

   The Comparisons and Procedures

   Comparisons with a baseline value are usually made between areas, times, and proposed or actual treatments.

   The Measures:

   Positive or negative change; change in percentage or proportion; squared difference are conventional measures. A chi-square test may suggests significant differences in the counts. Similarity indices: For example: The insects now are similar (0.89) to those during the baseline.

   Means (averages):

   The means appear to be different but a t test indicates the apparent difference could easily be due to chance.

   Variance:

   An F test indicates that the variance is now greatly reduced from that prior to the baseline.

   Range:

   The smallest values observed are identical in the two periods but a much larger value was observed in the recent work.

   Kurtosis:

   The baseline data were normal. The kurtosis is now e.g., some computed number, interpreted as, "strongly skewed toward the higher values." This is suggested by both of the above observations of variance and range.

   Baseline Photographs

   The photo record is designed to detail changes, or lack of change, in the topography, vegetation, and surroundings of the area. It is in opposition to current traditional research that covers a relatively short period, defines a problem, studies the conditions, and quantifies the results. Comparing photographs made years apart can provide an opportunity to investigate changes in wildlands and relations within them. It has been done by many people. I am of the view that historians and natural resource managers need an understanding of the long past for they must decide for the long future. Gruell (1980) said that "there is often a misunderstanding of landscape changes", misunderstanding we cannot afford. Early photographs, documents, and other evidence can "...help clarify what has happened to the landscape and help us in land management planning today." Gruell (1980) invited biologists, geologists, and others to "read" pairs of old and recent photographs. This is very difficult, but it can be done by experienced observers. Gruell (1980) mentioned the need for many pictures on a variety of sites to allow an objective evaluation. Evident problems with the technique include poor quality film, duplication of scenes, unknown locations, and views obstructed by natural or human development. Pre-planning is necessary to allow photographs to be taken at the same place, season, time of day, and weather condition. The rate at which "permanent" picture points disappear is, itself, a baseline observation. A photo record is planned to be established.

   Unifying Baseline Studies with Environmental Models

   Baseline studies in the past have extensive sets of observations, data collections, files, and reports. They have been descriptive. They are analyses awaiting events to negate them. Their value was highly speculative, a high investment with a very uncertain payoff on an unspecified date at an unspecified and variable interest rate.

   We seek to understand each area but first we must understand "to understand." For the modern citizen, understand means that we want to know an area well, so well that we can predict what it will do or be next under normal conditions or to what it will change if influenced by some outside forces. We topically want to use the baseline as a giant simile. We want to use our deductive powers of: if area X is like the baseline, then the factors, processes, phenomena, and forecasts will be approximately the same.

   Within Guidance are the concerns, on a limited scale, of those expressed in the Tbilis, Georgia, USSR, symposium in 1974 (EPA 1975). These and others are:

   1. Completely accounting pollution sources and receptors;
   2. Describing types of impacts and biophysical reactions;
   3. Making adjustments to standardize results, given the peculiarities of areas;
   4. Describing dose-response relations;
   6. Improving environmental monitoring techniques, especially for monitoring critical links and sensitive points; Describing the fate and effects of multiple pollutants;
   7. Listing standards (maximum levels) for pollutants and land developments;
   8. Listing standards for long- and short-term dosages of select environmental pollutants;
   9. Measuring and evaluating the response of ecosystems to varying environmental conditions such as global warming or radiation spectrum changes;
   10. Creating systems for determining permissible environmental loading;
   11. Developing practical quantitative methods which will permit comprehensive environmental analyses to be made and applied to environmental problems;
   12. Evaluating possible economic damage from environmental impacts;
   13. Developing cooperative, cost-effective monitoring, inventory, and research systems addressing the above needs.

   Not as expansive as the above list, the philosophy within Guidance is one that baseline studies may be and need to be wed to regular, short-term analyses of change and to predictive models with model validation, then used with corrective feedback as part of an on-going clarification of the past, improved estimates of the present, and insightful predictions and scenarios of the future. Descriptive information on large-scale ecosystems could prove more meaningful if structured to accomplish "ecological characterization." An ecological characterization is a description of the current important components and processes comprising an ecosystem and an understanding of their functional relationships. A guiding element in the characterization is a conceptual or descriptive model. Ecological classification systems based on hierarchical concepts, combined with conceptual ecosystem modelling emphasizing simple linear processes or rules should help provide a structured approach to the definition of reasonable study boundaries.

   To these ends, a set of models that is representative of what is believed to be a universal set of general land uses or types of human-related changes to wildland and related ecosystems have been formulated. Work will continue as resources become available. The universal set is for events in space. Each will include change over time, usually tied to the concept of ecological succession and using the concept of probable transitions. The set is of: points, lines, areas, and volumes. (Throughout ecology, there are strong relations among these four.) The strategy planned for the future (not in order of development) includes creating ecological and economic computer models, typically simulations. The models produce estimates of likely or expected future consequences of work on the area in each of the following major spatial categories (with examples).

   Points

   1. Building a single structure (e.g., a tower, a building, an ampitheatre)
   2. Experiencing a point catastrophe (e.g., a small fire, an airplane crash)

      Lines (or Corridors)

   3. Placing an underground pipeline
   4. Placing a road or trail
   5. Placing a powerline

      Areas

   6. Effects of wild fire (consequence tables)
   7. Deer harvest in the country
   8. Timber harvest (hypothetical)
   9. Gypsy moth effects (on stand composition and other factors)
   10. Insecticide use for gypsy moth control (primary emphasis on litter decomposition)
   11. Wildland preservation (primary emphasis on litter, residue, and fuel buildings)
   12. Litter and residue buildup (effective on rodents and raptors)
   13. Trail use (emphasis on water budget) and user perception of "crowded")
   14. Heavy metal build up from traffic (effects on litter decomposition)
   15. Levels of human use (on noisescape)
   16. Temperature change (e.g., global warming)
   17. Solar spectrum change (e.g., ozone layer depletion) on forest stand structure
   18. Forest stand structure changes (on faunal richness, abundance, and diversity)

       Volumes

   19. Pumping of groundwater
   20. Timber harvest or area preservation on the multilayered ecosystem volume
   21. Estimating pollutants in air over an ecosystem.

Many such models have been created in the past by scientists and agencies. Suggestions are sought for how to obtain existing models and to get them operational within Guidance. The models can be created one at a time. Great efficiencies due to synergism can be experienced by joint work on several or all of them simultaneously.

General

Baseline studies can be very expensive. Some require expensive equipment and logistic support. The direct cost of preserving land and protecting it are high -- as well as are the accumulated foregone benefits usually associated with such protection. Difficulties arise in the concept, for without it there can be little assurance that a scientifically sound program will emerge for determining changes. Without assurances, study funds can be claimed to be wasted. "Baseline" studies have been thrown in with impact studies for criticism due to their ineffective design and execution and "...emphasis on indigestible descriptive data." Other criticism has been directed at the enormous costs of museums, libraries, data storage, photo storage, and low scientific returns (Hirsch 1980:85). "Even if these major obstacles to the design of meaningful studies can be overcome, the baseline approach is probably of quite limited value unless it is an integral part of a much larger effort to address ecosystem characteristics and dynamics" (Hirsch 1980:91). Overcoming this latter criticism, and some of the others may be achievable through modeling within R* Guidance.

Literature Cited

Bratton, S. D. 1989. Environmental monitoring in wilderness, p. 103-112 in H. R. Freilich compiler, wilderness benchmark 1988: Proc. of the Natl. Wilderness Colloquirum, USDA For. Serv. S. E. Forest Exp. Sta., Gen. Tech. Rpt. SE-51, Ashville, NC. 228 pp.

EPA. 1975. Proceedings of the first US/USSR symposium on comprehensive analysis of the environment. EPA, 600/9-75-004, Washington, D.C. 188 pp

Gogan, P. J. P. and R. H. Barrett. 1986. Tule elk at Point Reyes National Seashore, p. 32-81 in F. S. Singer, Ed. Wildlife management and habitats: Proc. of the Conf. on Science in National Parks, Vol. 2, Colorado State Univ., Ft. Collins, CO. 184 pp.

Greene, S. E. and J. F. Franklin. 1989. The state of ecological research in Forest Service wilderness, p. 113-119 in H. R. Freilich compiler, wilderness benchmark 1988: Proc. of the Natl. Wilderness Colloquirum, USDA For. Serv. S. E. Forest Exp. Sta., Gen. Tech. Rpt. SE-51, Ashville, NC. 228 pp.

Gruell, G. E. 1980. Five's influence on wildlife habitat on the Bridger-Tetan National Forest, Wyoming. Vol. 1 - Photographic record and analysis. U.S.D.A. For. Serv. Res. Paper INT-235, Internt. For. and Range Exp. Sta., Ogden, Utah, 207 pp.

Hirsch, A. 1980. The baseline study as a tool in environmental impact assessment, p. 84-93 in Biological evaluation of environmental impacts: Proc. of a Symposium in 1976, U.S. Fish and Wildlife Service, Washington, D.C. FWS/OBS-80/26, 237 pp.

Jensen, C. E. 1979. e-k, a function for the modeler. USDA For. Serv., Intermountain For. and Range Exp. Sta., Res. Paper. INT-240, Ogden, Utah. 8 pp.

Leopold, A. 1949. A Sand County almanac and sketches here and there. Oxford Univ. Press. New York, N.Y. 226 pp.

Lacate. 1973. Collecting, storing, and evaluating data for nature conservation purposes. p. 13-25 in A. B. Costin and R. H. Groves eds. Nature Conservation in the Pacific, AUN Press, Australian National University.

Ohmann, L. F. and R. R. Ream. 1971. Wilderness ecology: a method of sampling and summarizing data for plant community classification, USDA For. Service, North Central For. Exp. Sta., NC-49, St. Paul, MN, 14 pp.

Patil, G. P. and C. Tallie. 1982. Diversity as a concept and its measurement. J. Am. Stat. Assoc. 77:548-561.

Peterman, R. M. 1990. The importance of reporting statistical power: the forest decline and acidic deposition example. Ecology 71(5):2024-2027.

Raine, R. M., J. L. Kansas, B. Shelast, and J. Martin. 1990. Biophysical inventory of the Siffleur and White Goat Wilderness Areas, Alberta Recreational and Parks, Provincial Parks Service, Report by Beak Associates Consulting Ltd., Calgary, Alberta (Abstract).

Ratliff, R. D. and S. R. Mori. 1993. Squared Euclidian distance; a statistical test to evaluate plant community change. U.S.D.A. Forest Serv. Res. Note PSW-416, Pacific Southwest Res. Sta., Berkeley, CA 4 pp.

SCOPE. 1971. Global environmental monitoring: a report submitted to the United Nations Conference on the Human Environment, Stockholm, 1972. Stockholm. 67 pp.

Sokol, R. R. and F. J. Rolf. 1969. Biometry, W. H. Freeman Co., San Francisco, CA 776 pp.

Tiarks, A. E., M. S. Kimble, M. L. Elliott-Smith. 1991. The first location of a national, long-term forest soil productivity study: methods of compaction and residue removal. P. 431-442 in S. S. Coleman and D. G. Neary, eds. Proc. 6th Biennial Silvicultural Research Conf. Vol. 1. Gen. Tech Rpt. SE-70, Ashville, NC.