2.1. Preliminaries

The definition of the language is standard, except that there is a special one-place predicate $\exists !$ and in some systems the operator . As usual in proof-theoretic investigation, I assume that there is an unlimited stock of variables, called parameters, used as free variables, distinct in shape from those whose occurrences are bound by quantifiers: $a, b \ldots $ for the former, $x, y, z\ldots $ for the latter. Constants are designated by $c, d\ldots $ , predicate letters by $P, Q, R\ldots $ , identity by $=$ , and the ‘existence predicate’, indicating that a term refers, by $\exists !$ . $A, B\ldots F, G \ldots $ range over formulas. If necessary, subscripts are used. The connectives are $\bot $ , $\land $ , $\lor $ , $\rightarrow $ , $\exists $ and $\forall $ . $\neg A$ is defined as $A\rightarrow \bot $ . takes a variable and a formula F and forms a singular term out of them, , where x is bound by in F. The terms of the language are the constants, parameters and the terms, the former two atomic, the latter complex. t ranges over terms. $A_t^x$ names the formula that results from replacing the term t for all free occurrences of x in A. The distinction between parameters and bound variables ensures that replacements of terms in formulas is always possible.

Deductions are defined as usual as certain kinds of trees labeled with formulas. I follow Troelstra’s and Schwichtenberg’s conventions for the discharge or closing of assumptions [Reference Troestra and Schwichtenberg37, sec 2.1.1]: assumptions are assigned assumption classes, rules close or discharge all formulas in an assumption class, indicated by square brackets around the formulas in that class and a numeral to their right and to the right of the inference at which these assumptions are closed or discharged. Empty assumption classes, for vacuous discharge, are permitted. I’ll use $\Pi $ , $\Xi $ , $\Sigma $ to stand for deductions, often, as is customary, displaying their conclusions below and some assumptions on top.

2.2. Intuitionist negative free logic

These are the rules of Tennant’s system of intuitionist negative free logic $\mathbf {INF}$ [Reference Tennant32, sec. 7.10]:

where in $(\forall I)$ , a does not occur in $\forall xA$ nor in any undischarged assumptions of $\Pi $ except those in the assumption class of $\exists !a$ .

where in $(\exists E)$ , a is not free in C, nor in $\exists xA$ , nor in any undischarged assumptions of $\Pi $ except those in the assumption classes of $A_a^x$ and $\exists ! a$ .

where R is an n-place predicate letter (but not $\exists !$ ) or identity and $1\leq i\leq n$ .

The superscript n of $(=I^n)$ indicates that this is in the introduction rule for identity in negative free logic. $(AD)$ , the rule of atomic denotation, is typical for negative free logic: an atomic sentence can only be assertible or true if all terms that occur in it refer.

I will often omit labels of rules in deductions, especially when they are simple and the rules mentioned in the surrounding text, but I’ll add them where I think this helps understanding, especially when deductions are more complex and the rules involved less familiar.

$\exists !$ is in one sense redundant, as what is often called Hintikka’s Law holds:Footnote ⁷

$\vdash \exists ! t\leftrightarrow \exists x \ x=t.$

In another sense it makes good sense to keep it primitive, if the meanings of the quantifiers are to be defined by the rules governing them, as they are by Tennant: without it, the definition of the meaning of the existential quantifier would be circular.

2.3. Intuitionist negative free logic with a definite description operator

The system results by adding the operator and Tennant’s introduction and elimination rules for it to $\mathbf {INF}$ [Reference Tennant32, sec. 7.10]:

where a does not occur in , nor in t, nor in any undischarged assumptions except those in the assumption classes of $a=t$ in $\Xi $ or of $F_a^x$ and $\exists ! a$ in $\Pi $ .

is a special case of the rule $(AD)$ . But it is properly regarded as an elimination rule for , for, as we’ll see, there is a reduction procedure for maximal formulas of the form that have been concluded by and are premises of . So whenever $(AD)$ could be applied to the conclusion of , that is, when it is concluded that the right term refers, this is regarded as an application of . If it is the left term, the rule is $(AD)$ .

The rules for are what is now often called Lambert’s Axiom in rule form:

(LA)

is thus an intuitionist version of the minimal theory of definite descriptions in negative free logic.Footnote ⁸

A second axiom of Lambert’s, sometimes called ‘cancellation’,

(CA)

is provable conditionally on the existence of t by an application of in which F is $x=t$ and $\exists !a$ in the rightmost subdeduction is discharged vacuously:

2.4. Classical negative free logic with and without a definite description operator

$\mathbf {CNF}$ has the introduction and elimination rules for $\rightarrow $ , $\forall $ and $=$ , $(AD)$ and $(\bot E_C)$ :

Vacuous discharged being permitted, $(\bot E)$ is a special case of $(\bot E_C)$ . I’ll refer to these applications of $(\bot E_C)$ by the former label.

results by adding and its rules to $\mathbf {CNF}$ .

2.5. Two simplifying lemmas

The two lemmas in this section absolve us from having to consider certain tiresome cases in the normalisation theorem.

Lemma 1 holds for all the systems to be considered. More interesting and as far as I know new to the literature is the following:

Proof. (i) Evidently it is unnecessary to conclude $\bot $ from $\bot $ by $(\bot E)$ . (ii) By a well known and standard result, $(\bot E)$ may be restricted to atomic conclusions. Thus it suffices to consider the case where the conclusion of $(\bot E)$ is an atomic formula. We’ll first reduce these cases to identities flanked by only one term and then treat those.

(iii) Let G be either $\exists !$ or $=$ flanked by two terms or an $(n+m)$ -place predicate letter, $1<n, 0\leq m$ , forming a formula with terms and m atomic terms, the latter left implicit below:

These cases can all be reduced to applications of $(\bot E)$ to identities flanked by only one term by the following method. Take n fresh parameters $a_1\ldots a_n$ and infer and $G(a_1\ldots a_n)$ by $n+1$ applications of $(\bot E)$ , then apply $(=E)\ n$ times to deduce :

When G is an identity flanked by two terms, , there is a shorter method, as , but the method above works, too.

(iv) This leaves the case of an identity flanked by one term. As $=$ is symmetric, it suffices to consider the case:

where b is a an atomic term. Apply with vacuous discharge, where a is a fresh parameter:

F may be a complex formula or $\bot $ and contain further terms, so to establish the lemma, parts (i)–(iv) may need to be applied again. (i) is trivial: delete an application of $(\bot E)$ that concludes $\bot $ immediately whenever it arises as part of the procedure. The method for establishing (ii) reduces the number of connectives and quantifiers in conclusions of $(\bot E)$ . The methods of (iii) and (iv) reduce in addition the number of s in conclusions of $(\bot E)$ . The result, therefore, can be established by an induction over the complexity of conclusions of $(\bot E)$ . For the purposes of this lemma, let the degree for a formula be the sum of connectives, quantifiers and s in it. The measure $\langle d, e\rangle $ , ordered lexicographically, will do, where d is the highest degree of any conclusion of $(\bot E)$ , and e is the number of conclusions of $(\bot E)$ of highest degree. Applying any of the procedures in (ii), (iii), or (iv) either reduces e or, if there is only one conclusion of $(\bot E)$ of highest degree, reduces d.

Lemma 2 holds for $\mathbf {INF}$ , and carries over to $\mathbf {CNF}$ and $(\bot E_C)$ : its conclusion, too, can be restricted to prime formulas (here the same as the atomic ones).

Lemma 2 does not carry over to $(\bot E_C)$ in : when discharge is not vacuous, conclusions of $(\bot E_C)$ cannot be restricted to prime, but only to atomic conclusions: conclusions containing terms must be admitted, but only atomic ones. It would go too far to give a rigorous proof of this result here, and in any case, a further restriction is not needed for the normalisation proof to be given later. The following should suffice to elucidate the reason why the result fails. To show that $(\bot E_C)$ need not be applied to conclude a complex formula A, the usual procedure is to apply an elimination rule for the main operator of A, derive $\bot $ by assuming the negation of a subformula of A, conclude $\neg A$ , apply $(\bot E_C)$ to the subformula, and to do so as often as required to apply an introduction rule for the main operator of A to conclude A and discharge any auxiliary assumptions. This method does not work here. Suppose . We could take a fresh parameter b and conclude $F_b^x$ by from and $b=a$ , assume $\neg F_b^x$ to derive $\bot $ , and so deduce ; thus $\Gamma , b=a\vdash F_b^x$ . We could apply to and $\exists !b$ to derive $b=a$ , assume $\neg \ b=a$ to derive $\bot $ and so deduce ; thus $\Gamma , F_b^x, \exists !b\vdash b=a$ . Thus we have the two left deductions required for an application of . But we do not have $\exists !b$ , and there is no way to derive it from the material we are given. Besides, even with $\exists !b$ we’d only be able to derive , not , as requires a fresh parameter. The situation is no better for atomic formulas other than identities. To avoid concluding we’d need a formula to conclude from $\neg P(a)$ , and there is no way to discharge it.

Henceforth I shall assume all applications of $(=E)$ , $(\bot E)$ and $(\bot E_C)$ to be restricted according to Lemmas 1 and 2. That is, in , applications of $(\bot E_C)$ with vacuous discharge are assumed to have prime conclusions, just as for applications of $(\bot E)$ in .

3.1. General notions

As usual, I assume that in any application of rules with restrictions on parameters the parameter is introduced into the deduction solely for the purpose of that application of the rule, occurring nowhere else.Footnote ⁹ This ensures that in the transformations applied to deductions in the process of normalisation, no ‘clashes’ of variables can occur. $\Pi _t^a$ names the deduction that results from replacing the term t for all occurrences of the parameter a in $\Pi $ . indicates that $\Pi $ is used to conclude all assumptions in the assumption class of A in $\Sigma $ . This notation is used to indicate that formulas discharged by a rule in one deduction are instead concluded by another rule in a transformed deduction.

Applications of $(\lor E)$ and $(\exists E)$ give rise to sequences of formulas of the same shape, all minor premises and conclusions of $(\lor E)$ or $(\exists E)$ , except the first and the last ones: the first is only a minor premise, the last only a conclusion. It is convenient to capture this situation in a way that covers every formula in a deduction (cf. [Reference Prawitz26, p. 49] and [Reference Troestra and Schwichtenberg37, p. 179]):

I’ll say that C is on a segment and speak of segments as being premises, conclusions, discharged assumptions of rules depending on whether their last or first formulas are.

A segment of length $1$ is a formula, and I shall often refer to them as such. Occasionally I shall use the pleonasm ‘formula or segment’.

Definition 4 ignores a minor issue. Call an application of $(=E)$ vacuous if the major premise is $t=t$ . The definition ignores the possibility that the formulas on a segment are minor premises and conclusions of vacuous applications of $(=E)$ . However, as then the minor premise and the conclusion of $(=E)$ are identical, they can evidently be removed from deductions without loss and without trouble. Including this possibility is a needless complication. Vacuous applications of $(=E)$ can arise as a result of the transformations of deductions in normalisation procedures. I shall assume that they are always removed together with the procedure. I shall leave this largely implicit, but as a reminder that they may occur, I shall at various points mention vacuous applications of $(=E)$ .

Accordingly a maximal formula is a formula occurrence that is the conclusion of an introduction rule and the major premise of an elimination rule.

The degree of a formula is normally defined as the number of logical symbols occurring in it. For our purposes, however, quantifiers need to count for two because of the existence assumptions in their rules. This ensures that $\forall xA$ and $\exists xA$ always have a higher complexity than the premises and discharged assumptions of their introduction rules. This is not needed for , as counting and $=$ as one each, always has a higher complexity than any premise or discharged assumption of (at least 2). The degree $d(A)$ of a formula A and $d(t)$ of terms is defined by simultaneous induction as follows:

The degree of a segment is the degree of the formula on it.

3.2. Failure of the subformula property

As I won’t consider the subformula property for systems with , the definition of subformula is standard:

The subformula property is usually defined as follows:

This fails already in standard first-order logic with identity. For instance:

$Rt_2t_3$ is not a subformula of any other formula, and there is no way to rearrange the deduction to change this. It also fails due to rules specific to negative free logic. For instance, to deduce $A_t^x$ from $\forall xA$ requires $\exists !t$ , which we may be able to infer from an atomic formula $Pt$ :

$\exists !t$ need not be a subformula of another formula, and there may be no way to rearrange this deduction. Identity gives rise to further cases, e.g., to conclude $t=t$ by $(=I^n)$ requires $\exists !t$ , which may be concluded from $Pt$ .

This circumscribes where exceptions to the subformula property are found. I will later define a restricted version that holds for deductions in $\mathbf {INF}$ and $\mathbf {CNF}$ .

Comment. I am not regarding $(AD)$ as an introduction rule for $\exists !$ , nor $(\exists I)$ , $(\forall E)$ and $(=I^n)$ as elimination rules for it. There are philosophical questions that arise here, which I will discuss briefly on p. 19. and p. 22. An extended discussion must wait for another occasion.Footnote ¹⁰

3.3. Maximal segments specific to negative free logic

Maximal formulas arise because of detours in deductions, to use Gentzen’s phrase. Normalisation theorems show that these detours can be avoided. They are unnecessary to derive the conclusion. The process of normalisation may also remove unnecessary assumptions from the deduction. The thought is that a proof in normal form appeals only to what is essential to prove the conclusion.

The rules of negative free logic give rise to detours in addition to those of Definition 5. For instance, $(=I^n)$ followed by $(AD)$ and sometimes conversely:

This is clearly unnecessary. Similarly when $t=t$ and $\exists !t$ are stretched out by $(\lor E)$ or $(\exists E)$ . In the systems with , could be applied instead of $(AD)$ , but this clearly makes no difference, as we can just rename the rule.

In $\mathbf {CNF}$ and we may speak of maximal $\exists !$ - and $=$ -formulas.

Recall that we are ignoring vacuous applications of $(=E)$ . This absolves us from considering the case that a maximal $=$ -segment contains what might be called totally vacuous applications of $(=E)$ , those where all three formulas of the inference are $t=t$ .

$(=E)$ gives rise to sequences of formulas quite similar to segments, except that terms are replaced in the formulas constituting the segment:

I’ll refer to the major premises to the left of formulas on an $(=E)$ -segment as the major premises of the segment.

$(=E)$ -segments can give rise to unnecessary detours, if $(AD)$ is applied to their last formulas or if their formulas have the form $\exists !t$ . For example:

These constructions involve terms that may not be needed to derive the conclusion. In the systems without , these would be atomic terms that name objects the existence of which may be irrelevant to proving the conclusion (by $(AD)$ , for any $t_j$ in (a) and (b), $\exists !t_j$ ). Free logic being concerned with the avoidance of existence assumptions, this is undesirable. In the systems with , there may in addition be complex terms that refer to objects by predicates that not are needed to prove the conclusion: this would be a case of introducing unnecessary concepts into the proof.

The $(=E)$ -segments can be omitted:

(a) If $i=3$ , $\exists !t_3$ could have been concluded by $(AD)$ from the minor premise of the first application of $(=E)$ ; if $i=4$ , $\exists !t_4$ could have been concluded by $(AD)$ from the major premise of the last application of $(=E)$ .

(b) $\exists !t_i$ could have been concluded by $(AD)$ from one of the major premises of $(=E)$ ; if one or more of $t_4, t_5$ or $t_6$ happens to be the same as $t_1, t_2$ or $t_3$ , $\exists !t_i$ could also have been concluded from the first formula of the segment.

(c) $\exists !t_4$ could have been concluded by $(AD)$ from the major premise of the last application of $(=E)$ .

Clearly this situation generalises, and also to cases with $(\lor E)$ or $(\exists E)$ interspersed. As before, in the systems with , could be applied instead of $(AD)$ , but this again makes no difference, and we just rename the rule.

To distinguish the maximal segments defined in this section from those defined in the last section, I’ll refer to the latter by ‘maximal $I/E$ -segments’ (for introduction/elimination). By ‘maximal segment’ I usually mean both, but sometimes only $I/E$ -segments, if it is clear from context what is meant.

The reduction procedures that remove the new maximal segments from deductions are as follows:

I. For maximal $\exists !$ - and $=$ -segments: remove the application of the rule that concludes the segment, the segment and the formula concluded from it (i.e., we proceed directly from the formula from which the segment is concluded to the rule applied to the formula concluded from the segment).

II. For maximal $(=E)$ -segments: (i) If the formula on the segment is formed from $\exists !$ and a term, conclude its last formula from the major premise of the last application of $(=E)$ , removing all the rest. (ii) If not, conclude $\exists !t_i$ from either the first formula of the segment or from the lowest major premise of an application of $(=E)$ that contains $t_i$ , removing all the rest.

3.4. Normal form and rank of deductions

The definition of normal form is standard:

Normalisation is proved by induction over the complexity of deductions, where maximal $\exists !$ -, $=$ - and $(=E)$ -segments are not counted, as they are taken care of by Lemma 3:

4.1. Normalisation

The reduction procedures for removing maximal segments of length 1 (i.e., formulas) with the sentential connectives as main operators are standard and won’t be repeated: they are those given by Prawitz [Reference Prawitz26, 35ff]. The permutative reduction procedures for shortening maximal segments of length longer than 1 are standard, too: for $(\lor E)$ they are those given by Prawitz [Reference Prawitz26, p. 51], for $(\exists E)$ a trivial variation of those given by him. The reduction procedures that remove applications of $(\lor E)$ and $(\exists E)$ in which vacuous discharge occurs are also as usual: applications of $(\lor E)$ in which no or only one assumption is discharged are evidently superfluous, similarly if no assumption is discharged by $(\exists E)$ . Applications of that rule that discharge only one assumption, however, are not superfluous and not removed, unless the major premise is derived by $(\exists I)$ .

The reduction procedures for maximal formulas with quantifiers as main operators do not pose much of a problem either, but Tennant omits them from [Reference Tennant32], and Troelstra and Schwichtenberg do not consider normalisation of a corresponding system [Reference Troestra and Schwichtenberg37, Sec. 6.5], so here they are. Replace the inferences on the left by those on the right:

4.2. Subformula property

The following modifies Prawitz’s notion of a path slightly to fit $\mathbf {INF}$ :

Paths are naturally divided into segments. Indeed, in the definition above, ‘segment’ could replace ‘formula’. I will speak of paths being in deductions and of formulas and segments being on paths.

The first part of a path may be called the E-part, the last the I-part, the one in the middle the M-part. Notice that the M-part is never empty. The following corollary establishes a result about the form of M-parts of paths in deductions in normal form. It is here that $(=E)$ and the rules specific to negative free logic, $(=I^n)$ and $(AD)$ , are applied, and because of normal form, these applications are only very limited and follow a certain order. For instance, if all three rules just mentioned are applied, they must be applied in the order $(AD)$ , $(=I^n)$ , $(=E)$ , where ( $=I^n)$ concludes the minor premise of $(=E)$ , and there follow no more applications of $(AD)$ or $(=I^n)$ .

In relation to the usual definition of subformula property we have the following:

6.1. A problem solved by a new rule for identity

For a normalisation theorem to be provable by induction over the complexity of formulas, we must count terms in addition to connectives and quantifiers, as was already done in Definition 6. This creates a problem with the reduction procedures for maximal formulas of form $\forall x A$ and $\exists xA$ : if t is a complex term, they may introduce maximal formulas of higher degree than those removed. There is no apparent systematic way of avoiding this, e.g., by applying the reduction procedures to a suitably chosen formula. Replacing a parameter by an term increases the complexity of the formula. Looking only at a maximal formula of highest degree, we do not know whether the replacement of a parameter by an term will not turn a maximal formula that had a lower than maximal degree before into one the degree of which is now higher.

The problem is most straightforwardly solved by an observation made by Indrzejczak [Reference Indrzejczak10, sec. 4] in relation to a number of free logics formulated in cut free sequent calculi: $(\forall E)$ and $(\exists I)$ can be restricted to atomic instantiating terms, given the rule of the next lemma, which is derivable in $\mathbf {INF}$ .

where the parameter a does not occur in t, C nor any open assumptions of $\Pi $ other than those of the assumption class of $a=t$ .

$(=I^{nG})$ is a new introduction rule for $=$ . It has the form of what Negri and von Plato [Reference Negri and von Plato25, p. 217] and Milne [Reference Milne23, Reference Milne and Wansing24] call general introduction rules. In its presence $(=I^n)$ is redundant:

Proof.

The symmetry of identity will play a prominent role in the following, so we prove it here, which also gives another example of a use of $(=I^{nG})$ :

Proof.

Notice once more how the subformula property cannot be upheld: $\exists !t_1$ , $a=t_1$ and $a=t_2$ are not subformulas of any undischarged premises or of the conclusion.

Now for the point of introducing $(=I^{nG})$ :

Proof. Any application of $(\exists I)$ and $(\forall E)$ where t is complex can be replaced by the following, where a is a fresh parameter:

The proof in fact shows something stronger: $(\forall E)$ and $(\exists I)$ can be restricted to parameters, as t might as well be a constant. But this is not needed in the following.

Comment. Kürbis [Reference Kürbis16, Reference Kürbis17] counts formulas discharged by general introduction rules that are the major premises of their elimination rules as maximal. There would, indeed, be a reduction procedure for such formulas, where all maximal formulas arising from an application of $(=I^{nG})$ are replaced together after the following pattern:

If there are non-maximal formulas in the assumption class of $a=t$ , then $\Pi _t^a\ast $ and $\Sigma _t^a\ast $ are the results of removing the ensuing vacuous applications of $(=E)$ . But this won’t work if t is an term. As before, the replacement of a by t in $\Pi $ and $\Sigma $ may then create maximal formulas of unknown degree. What is more, the use to which $(=I^{nG})$ is put in handing normalisation in the presence of prevents us from removing Kürbis-style maximal formulas from deductions: this use will generate maximal formulas of exactly that kind.

The following philosophical questions arise. Should we not demand that these formulas be removable from deductions? Furthermore, the deduction that derives $(=I^{nG})$ in the proof of Lemma 4 contains a maximal formula. So $(=I^{nG})$ comes at the cost of hiding a detour.Footnote ¹² This is not the place to address these questions exhaustively, so a sketch of an answer must suffice. The answer to both questions lies, I think, in the connection between reference and existence. If a definite description refers, i.e., if , then $(=I^{nG})$ permits the introduction of an ad hoc name for its referent. We can, that is, baptise the object, to use Kripke’s expression. This allows us to refer to it without having to describe it as an F. The significance of this comes out in modal contexts. The name is rigid, the definite description need not be. The move ensures that we can talk about the same object in every possible world. By contrast, we cannot baptise what does not exist; here all we have is the definite description. These are issues orthogonal to those of how the meanings of logical expressions are defined by their rules. So even if $(=I^{nG})$ hid or gave rise to unremovable maximal formulas, this would not upset the aims of proof-theoretic semantics. Further discussion of the wider issues touched upon here must wait for another occasion.

6.2. Reduction procedures for and restrictions of its rules

The reduction procedures for identities flanked by an term, the first two taken from [Reference Tennant32, p. 169], are the following:

1. followed by :

2. followed by :

3. followed by :

The same problem as for the quantifiers arises. If u is a complex term, $\Xi _u^a$ and $\Sigma _u^a$ may contain maximal formulas of higher degree than the formula that is removed by the first and second reduction procedures. A new problem is that if u is a complex term, $F_u^x$ can turn into a maximal formula of unknown degree. $u=t$ , $\exists !u$ and $\exists !t$ pose no problem, as, if maximal, they are handled by Lemma 3.

This problem is solved by the following lemma, which also builds on an observation of Indrzejczak’s [Reference Indrzejczak12]. In the following deductions, double lines mark inferences by symmetry of identity (Lemma 6).

Proof. (1) Replace an application of where t is a complex term by

where a and b are fresh parameters.

(2) (a) Replace an application of where t is a term and u atomic by

where a is a fresh parameter.

(b) Replace an application of where u is a term and t atomic by

where b is a fresh parameter.

(c) If both t and u are complex, either carry out procedure (a) and replace the inference by by the construction in (b), or carry out procedure (b) and replace the inference by the construction in (a).

If both t and u are complex, there are also two alternative methods that lead to less complex deductions. (i) Say u is . Then replace u in by a fresh parameter b, so that it concludes $F_b^x$ , derive from by $(=E)$ , and discharge the former by an application of $(=I^{nG})$ , with its premise derived from by $(AD)$ . Then apply construction (a). (ii) Say t is . Then replace t in by a fresh parameter a and discharge the ensuing formulas and $u=a$ by applications of $(=I^{nG})$ with their premises derived by $(AD)$ . Then apply construction (b).

(3) (a) Replace an application of where t is a term and u atomic by

where a is a fresh parameter.

(b) Replace an application of where u is a term and t atomic by

(c) If both t and u are complex, either carry out procedure (a) and replace the inference by by the construction in (b), or carry out procedure (b) and replace the inference by the construction in (a).

Here, too, when both t and u are complex, there are methods that lead to less complex deductions, but this is left to the reader.

Comment. The restriction on the rules for may have philosophical significance. Došen requires of an analysis of the meaning of an expression that a sentence in which it occurs only once is paraphrased by an equivalent sentence in which it does not occur [Reference Došen3, p. 369, 371f]. The reason is that otherwise it is not clear that the expression or rather a sequence of occurrences of that expression has been analysed. This requirement is reminiscent of one often imposed on rules of sequent calculi, especially those intended to define the meanings of connectives by their inference rules. Wansing calls rules in which the connective they govern occurs only once and only in the conclusion explicit (see [Reference Wansing39, p. 127], [Reference Wansing40, p. 10]). Although $(AD)$ cannot be so restricted, it may be motivated independently by a general requirement behind negative free logic: the truth or assertibility of an atomic proposition requires that all the terms occurring in it refer. Another criterion Wansing imposes is separation: no other connective than the one they govern is mentioned in the rules. The rules for do not satisfy separation, as identity occurs in them, but requiring separation is rather too stringent. It is a legitimate procedure to define one expression in terms of another. The meaning of the second expression then depends on the first. In set theory, e.g., operations on the numbers are defined after the numbers have been defined. What should be avoided is that such dependencies are circular.

6.3. Normalisation

Due to these problems and their solutions I will prove normalisation not for , but for the system that results from it by replacing $(=I^n)$ by $(=I^{nG})$ and restricting t in $(\forall E)$ , $(\exists I)$ and , and t and u in and to atomic terms. These systems are equivalent:

We need to modify some definitions. $(=I^{nG})$ is often treated similarly to $(\exists E)$ . The parameter of an application of $(=I^{nG})$ is assumed to be used solely for that application and to occur nowhere else in the deduction, and it also gives rise to segments:

Definition 5 stays the same. In Definition 14, paths continue with a discharged assumption from the premise of $(=I^{nG})$ , but we won’t have much occasion to consider this notion.

Definition 9 requires change and there is one more case to be considered:

If $\exists !a$ is concluded, this is not counted as maximal. Such segments are used in the proof that the rules for quantifiers and can be restricted. These are not detours and a formula different from the premise is concluded.

The new reduction procedures are as follows:

I. Maximal $=$ -segments (i): proceed from the rule that concludes the major premise to the rule applied to the maximal segment, removing all the rest. To illustrate the case where the last formula of the segment is the premise of $(AD)$ or :

II. Maximal $=$ -segments (ii): conclude the conclusion of $(AD)$ or from whatever concludes the major premise of $(=I^{nG})$ , leave everything else. To illustrate with a simple example:

The final application of $(=I^{nG})$ is required only if there are formulas in the assumption class of $a=t$ that are not premises of $(AD)$ or .

III. Analogous to I: proceed from the rule that concludes the major premise to the rule applied to the maximal segment, removing all the rest. To illustrate the case where the first formula of the segment is the premise of $(AD)$ or :

Should there be more than one application of $(=I^{nG})$ in the rules that give rise to the segment, pick the lowest one.

Lemma 3 goes through with a slight modification. In case II, if more than one formula $a=t$ is discharged and $\Pi $ is not empty, the new reduction procedure increases the number of applications of rules in a deduction and multiplies any maximal $\exists !$ -, $=$ - or $(=E)$ -segments in $\Pi $ .

6.4. Failure of the subformula property

I shan’t consider a modified subformula property for deductions in . There are too many exceptions. To give but one example, consider a derivation of ‘The F is G’, where G is not $=$ , arguably the more typical use of definite descriptions:

would need to be exempt from the subformula property.

There may be something systematic to the exceptions: they all involve $\exists !$ or $=$ . But further investigation of this question must await another occasion.